An anonymous reader quotes a report from CNBC: President Donald Trump said in a social media post on Monday that Microsoft will announce changes to ensure that Americans won't see rising utility bills as the company builds more data centers to meet rising artificial intelligence demand. "I never want Americans to pay higher Electricity bills because of Data Centers," Trump wrote on Truth Social. "Therefore, my Administration is working with major American Technology Companies to secure their commitment to the American People, and we will have much to announce in the coming weeks." [...] Trump congratulated Microsoft on its efforts to keep prices in check, suggesting that other companies will make similar commitments. "First up is Microsoft, who my team has been working with, and which will make major changes beginning this week to ensure that Americans don't 'pick up the tab' for their POWER consumption, in the form of paying higher Utility bills," Trump wrote on Monday. Utilities charged U.S. consumers 6% more for electricity in August from a year earlier, including in states with many data centers, CNBC reported in November. Microsoft is paying close to attention to the impact of its data centers on local residents. "I just want you to know we are doing everything we can, and I believe we're succeeding, in managing this issue well, so that you all don't have to pay more for electricity because of our presence," Brad Smith, the company's president and vice chair, said at a September town hall meeting in Wisconsin, where Microsoft is building an AI data center. While Microsoft is moving forward with some facilities, the company withdrew plans for a data center in Caledonia, Wisconsin, amid loud opposition to its efforts there. The project would would have been located 20 miles away from a data center in the village of Mount Pleasant.

Read more of this story at Slashdot.

The PC market is bracing for a turbulent year ahead, but shipments managed to exceed expectations in the recent holiday quarter. IDC reports that shipments grew nearly 10 percent year-over-year in the fourth quarter of 2025, reaching 76.4 million in total.

Microsoft's end of Windows 10 support undoubtedly helped push PC shipments up, but IDC notes that PC makers have also been aggressively pulling forward inventory to combat potential tariffs and the global memory shortage.

"While the holiday season typically drives stronger demand, the surge in late 2025 was further amplified by emerging memory shortages that led buyers and brands to secu …

Read the full story at The Verge.

Microsoft’s 5-point plan to partner with local communities across the United States

This year marks America’s 250^th year of independence. One of the trends that has repeatedly shaped the nation’s history is again in the news. As we’re experiencing at Microsoft, AI is the latest in a long line of new technologies to require large-scale infrastructure development.

Microsoft today is launching a new initiative to build what we call Community-First AI Infrastructure—a commitment to do this work differently than some others and to do it responsibly. This commits us to the concrete steps needed to be a good neighbor in the communities where we build, own, and operate our datacenters. It reflects our sense of civic responsibility as well as a broad and long-term view of what it will take to run a successful AI infrastructure business. In short, we will set a high bar.

As we launch this initiative, we think about it in the context of both the headlines of the day and the lessons from the past. Beginning in the 1770s, the country has advanced through successive eras built on huge infrastructure development based on canals, railroads, power plants, and the electrical grid, followed by the telephone system, highways, and airports. AI infrastructure has become the next chapter in this story.

Like major buildouts of the past, AI infrastructure is expensive and complex. Investments are advancing at a rapid pace. Today, these require large-scale spending by the private sector in land, construction, electricity, liquid cooling, high-bandwidth connectivity, and operations. This revives a longstanding question: how can our nation build transformative infrastructure in a way that strengthens, rather than strains, the local communities where it takes root?

Large AI investments are accelerating just as datacenter concerns are growing in local communities. The pattern is familiar. Whether it was canals, railroads, the electrical grid, or the interstate highway system, each era produced its own conflicts over who bore the burdens of progress. One enduring lesson is that successful infrastructure buildouts will only progress when communities feel that the gains outweigh the costs. Long-term success requires a commitment to address public needs, including by the private companies making these investments.

This must start by understanding local concerns. Residential electricity rates have recently risen in dozens of states, driven in part by several years of inflation, supply chain constraints, and long-overdue grid upgrades. Communities value new jobs and property tax revenue, but not if they come with higher power bills or tighter water supplies. Without addressing these issues directly, even supportive communities will question the role of datacenters in their backyard.

As a company, we believe in the many positive advances AI will bring to America’s future. From stronger economic growth to better medical advances and more affordable products, we believe AI will make a difference in everyday lives. But we also recognize that AI, like other fundamental technological shifts, will create new challenges as well. And we believe that tech companies like Microsoft have both a unique opportunity to help contribute to these advances and a heightened responsibility to address these challenges head-on.

This Community-First AI Infrastructure Initiative provides a framework for doing exactly that. It is anchored in five commitments, each a clear promise to the communities where we build, own, and operate Microsoft datacenters. These are:

1. We’ll pay our way to ensure our datacenters don’t increase your electricity prices.
2. We’ll minimize our water use and replenish more of your water than we use.
3. We’ll create jobs for your residents.
4. We’ll add to the tax base for your local hospitals, schools, parks, and libraries.
5. We’ll strengthen your community by investing in local AI training and nonprofits.

We describe our plans in detail below. We recognize that these will evolve and improve, based most importantly on what we learn from ongoing engagement with local communities across the country. We’ll also follow this plan for Community-First AI Infrastructure with similar plans for other countries, shaped to reflect their local needs and traditions.

But we are choosing the beginning of 2026 in Washington, DC to launch this effort in the United States. Our goal is to move quickly, partner with local communities, and bring these commitments to life in the first half of this year.

1.Electricity: We’ll pay our way to ensure our datacenters don’t increase your electricity prices.

There’s no denying that AI consumes large amounts of electricity. While advances in technology may someday change this, today, this is the reality.

The United States will retain its AI leadership role only if AI infrastructure can tap into a rapidly growing supply of electricity. The International Energy Agency (IEA) estimates that US datacenter electricity demand will more than triple by 2035, growing from 200 terawatt-hours to 640 terawatt-hours per year. This growth is taking place alongside rapid electrification of manufacturing and other sectors of the economy.

Our nation is addressing this reality at a demanding time. Even in the absence of datacenter construction, the United States is facing major electricity challenges. Much of the country’s electricity transmission infrastructure is more than 40 years old, and it’s under strain. Supply chain constraints on transformers and high-voltage equipment are delaying upgrades that would enable existing lines to deliver more electricity. New transmission can take more than 7 to 10 years due to permitting and siting delays. This creates a mismatch with growing electricity demand.

Some have suggested that AI will be so beneficial that the public should help pay for the added electricity the country needs for it. We believe in the benefits AI will create, but we disagree with this approach. Especially when tech companies are so profitable, we believe that it’s both unfair and politically unrealistic for our industry to ask the public to shoulder added electricity costs for AI. Instead, we believe the long-term success of AI infrastructure requires that tech companies pay their own way for the electricity costs they create.

This will require that we take four steps, and we’re committed to each:

First, we’ll ask utilities and public commissions to set our rates high enough to cover the electricity costs for our datacenters. This includes the costs of adding and using the electricity infrastructure needed for the datacenters we build, own, and operate. We will work closely with utility companies that set electricity prices and state commissions that approve these prices. Our goal is straightforward: to ensure that the electricity cost of serving our datacenters is not passed on to residential customers.

In some areas, communities are already starting to benefit from this approach. In Wyoming, for example, Microsoft and Black Hills Energy have developed an innovative utility partnership that ensures our datacenter growth strengthens—rather than burdens—the local community. And as part of our datacenter investment in Wisconsin, we are supporting a new rate structure that would charge “Very Large Customers,” including datacenters, the cost of the electricity required to serve them. This protects residents by preventing those costs from being passed on. But we recognize the need to ensure that datacenter communities benefit everywhere. We believe this approach can and should be a model for other states.

Second, we’ll collaborate early, closely, and transparently with local utilities to add electricity and the supporting infrastructure to the grid when needed for our datacenters. Addressing electricity costs is critical, but it is an incomplete solution for local communities unless we expand electricity supply. This expansion typically requires a complex effort that includes the expansion of electrical generation capacity and improvements in transmission and substation systems.

We’re committed to collaborating with local utilities. We will sit down and plan together, providing early transparency around our projected power requirements and contracting in advance for the electricity we will use. When our datacenter expansion requires improvements in transmission and substation capabilities, we will continue our existing practices by paying for these improvements.

This work will build on a spirit of partnership with utilities we’ve worked to foster across the country. For example, in the wholesale energy market that covers much of the Midwest called the Midcontinent Independent System Operator (MISO), we have contracted to add 7.9 GW of new electricity generation to the grid, which is more than double our current consumption.

Third, we’ll pursue innovation to make our datacenters more efficient. We are also using AI to reduce energy use and improve the performance of our software and hardware in the design and management of our datacenters. And we are collaborating closely with utilities to leverage tools like AI to improve planning, get more electricity from existing lines and equipment, improve system resilience and durability, and speed the development of new infrastructure, including nuclear energy technologies.

By embedding these innovations into datacenters and by collaborating directly with local utilities, communities gain access to systems that are more efficient, more reliable, and better prepared to support growth without increasing costs for households.

Fourth, we’ll advocate for the state and national public policies needed to support our neighboring communities with affordable, reliable, and sustainable power. Public policy plays an essential role in supporting communities with affordable, reliable, and sustainable access to electricity. In 2022, Microsoft established priorities for electricity policy advocacy: expanding clean electricity generation, modernizing the grid, and engaging local communities. Over the past three years, we have advocated across all three areas and engaged with government leaders at the federal, state, and local levels to do so. To date, however, progress has been uneven. This needs to change.

We will advocate for policies across these areas with an urgent focus on accelerating project permitting and interconnection of electricity projects, expediting the planning and expansion of the electricity grid, and designing new electricity rates for large electricity users.

2. Water: We’ll minimize our water use and replenish more of your water than we use.

Across the country, communities are asking pointed questions about how datacenters use water. These are arising in places already facing water stress, like Phoenix and Atlanta, as well as regions with more abundant supply, like Wisconsin. These concerns are often amplified by aging municipal water systems and infrastructure gaps. Local communities want and deserve reassurance that new AI infrastructure won’t strain their water resources.

Our commitment ensures that our presence will strengthen local water systems rather than burden them. We’ll do this by reducing the amount of water we use and by investing in local water systems and water replenishment projects.

First, we’re committed to reducing the amount of water our datacenters use. The chips that power datacenters produce heat. To manage that heat, datacenters historically relied upon evaporative cooling systems that drew on large volumes of water for cooling in hot weather. As AI workloads have increased, the demand for cooling has increased. The GPU chips that power AI workloads run at very high temperatures; without proper cooling, these chips would burn out within minutes.

The good news is that the tech sector has invested in new innovations to address these cooling needs. Now is the time when we need to step up, use these new technologies, and take added steps to address water use concerns.

Across our entire owned fleet of datacenters, we are committed as a company to a 40 percent improvement in datacenter water-use intensity by 2030. We are optimizing water usage for cooling, improving our ability to balance between water-based cooling and air cooling based on environmental conditions. We have also launched a new AI datacenter design that uses a closed-loop system. By constantly recirculating a cooling liquid, we can dramatically cut our water usage. In this next-generation design, already deployed in locations such as Wisconsin and Georgia, potable water is no longer needed for cooling, reducing pressure on local freshwater systems.

For communities where water infrastructure constraints pose challenges, we will collaborate with local utilities to understand whether current systems can support the additional demand associated with datacenter growth. If sufficient capacity does not exist, we work with our engineering teams to identify solutions that avoid burdening the community.

This approach will build on what we’ve learned from the recent work at our datacenters in Quincy, Washington, an arid region where the local groundwater supply was already under pressure. To avoid drawing from the community’s potable water, we partnered with the city to construct the Quincy Water Reuse Utility, which treats and recirculates datacenter cooling water rather than relying on local groundwater. This approach protects limited drinking-water supplies while ensuring that high-quality, recycled water can be used for datacenter cooling needs. Where future system improvements are required, Microsoft funds those upgrades in full, ensuring that the community doesn’t have to shoulder the cost of supporting our operations.

We also partner with utilities from day one to map out water, wastewater, and pressure needs, and we fully fund the infrastructure required for growth, ensuring local water systems are resilient. Beyond our own footprint, we invest directly in community water infrastructure, modernizing water systems, expanding access, increasing water reliability, and helping utilities maintain stable rates and pressure. For example, near our datacenter in Leesburg, Virginia, Microsoft is funding more than $25 million of water and sewer improvements to ensure the cost of serving our facilities does not fall on local ratepayers.

Second, we will ensure that we replenish more water than we withdraw. This means restoring measurable amounts of water to the same water districts where our datacenter’s water is used, so the total water returned exceeds total water used. This standard provides greater transparency and precision in tracking and reporting, aligned with emerging industry standards.

We will pursue projects that make the most important water contribution to each local community. For example, in the greater Phoenix area and nearby Nevada communities, our leak detection partnerships with local utilities identify and repair hidden breaks in aging water systems, preventing water losses and keeping municipal water in circulation for community use. These projects both add to the total usable water supply and improve the reliability of service for residents.

Across the Midwest, we are restoring historic oxbow wetlands. These are crescent-shaped water bodies that naturally recharge groundwater, reduce flood risk, and enhance habitats for native species. These wetlands act as nature’s reservoirs, capturing and slowly returning water to local aquifers throughout both wet seasons and droughts, creating year-round value for farms, ecosystems, and nearby communities.

Overall, we approach replenishment the same way a household might think about a bank account: our operations make water withdrawals, and our replenishment projects make deposits. Some deposits, like our leak detection projects, go straight into the checking account—depositing water into the municipal supply for immediate community use. Others, like wetland restoration, go into a savings account—investing in the watershed’s long-term capacity to store and supply the region. These projects are evaluated using recognized methods that convert on-the-ground improvements into measurable gallons (or cubic meters) of water restored to local ecosystems, ensuring that commitments reflect tangible local benefits, not abstract promises.

Third, we will support this work with greater local transparency. People deserve to know how much water our datacenters use, and we are committed to making that information accessible, clear, and easy to understand. Aligned with this goal, we will begin publishing water-use data for each datacenter region in the country, as well as our progress on replenishment. This approach will ensure that communities can understand both our operational footprint and the progress we are making against our water-positive goals.

Fourth, we will advocate for public policies to help minimize water use and strengthen resilience. This means championing policies that enable sustainable growth while safeguarding community resources. We will support state and federal efforts to make reclaimed and industrial recycled water the default supply for datacenters wherever feasible. We will advocate for harmonized transparency standards that allow communities to clearly understand water use and stewardship practices. And we will work to reduce permitting delays by promoting predictable pathways for water-efficient datacenter projects.

These actions reflect our belief that technology and environmental responsibility must advance together, ensuring that AI-driven progress aligns with long-term water resilience for people, places, and ecosystems. Our policy activities are rooted in protecting local communities. By prioritizing recycled water and efficiency, we will help reduce pressure on aging municipal systems and ensure reliable water access for people and businesses.

3.We’ll create jobs for your residents.

New datacenters create jobs—typically thousands during construction and hundreds during operations. For example, in Washington state more than 1,300 skilled trades workers are building Microsoft datacenters and by the end of next year more than 650 full-time employees and contractors will work across all our operational facilities there.

One of our goals is to help ensure that workers from the local community benefit from these opportunities. To achieve this, we will invest in new partnerships to help give local residents the skills and opportunities to fill these jobs in both the construction and operational phases.

The AI infrastructure construction boom is driving large-scale physical development, creating a huge demand for skilled tradespeople nationwide. As datacenters and the energy projects that support them grow quickly, firms are vying for a limited workforce. At one level, this is good news for people who already have the qualifications these jobs require. But at another level, there is a risk the jobs will not go to local residents who want to pursue these jobs unless they can acquire the skills required.

We will take a multifaceted approach.

First, we will invest in partnerships to help train local workers to support the construction and maintenance of datacenters. This includes a new and first-of-its-kind partnership between Microsoft and North America’s Building Trades Unions (NABTU) to strengthen apprenticeship and training programs in the skilled trades where datacenters are being built. We are launching today a new agreement that establishes a cooperative framework to focus on building a pipeline of skilled workers in regions where we are building datacenters. This will also help enable NABTU to identify qualified contractor partners to bid on our infrastructure projects.

Second, we will expand our Datacenter Academy program to train individuals to fill ongoing datacenter operations roles. This program works in partnership with local community colleges and vocational schools to train students for critical roles in datacenter operations and related careers, once construction is complete.

A good example of this work is our Datacenter Academy partnerships in Boydton, Virginia, where we have a large datacenter campus. The Academy works with Southside Virginia Community College and the Southern Virginia Higher Education Center, which have helped hundreds of students and adult learners earn industry-recognized certifications in information technology and critical facilities operations.

In 2024, this work expanded with the opening of a new Critical Environment Training Lab (SoVA) in South Hill. This provides hands-on training with electrical, mechanical, and cooling systems using decommissioned datacenter equipment donated by Microsoft. Graduates of these programs have gone on to pursue careers supporting datacenter operations in Southern Virginia, including roles with Microsoft and the broader ecosystem of companies that help operate and maintain digital infrastructure. We will pursue similar partnerships in other states, and we are committed to making this an ongoing part of our work in the communities where we build new datacenters.

Third, we will use our voice to encourage policymakers to support these new job opportunities. While this work is of heightened importance in communities with datacenters, the broader need for this type of skilled labor is national in scope. According to LinkedIn data, job postings for data center occupations or requiring at least one core data center skill, such as data center operations, grew by 23 percent globally and 13.5 percent in the US year-over-year in 2025. This is likely to represent an ongoing trend. Over the next decade, trillions in private investment will offer steady employment opportunities for American workers—including electricians, pipefitters, HVAC techs, welders, and construction crews—alongside manufacturing technicians for related components, like chips, power generation, and cooling systems.

However, this rapid demand for skilled labor is set to outpace the available pipeline of workers. Today, the Associated Builders and Contractors estimates that the construction industry is short roughly 439,000 workers, mostly among skilled workers who do things like lay pipe and wire electrical panels.[1] Manufacturers report shortages as well, with the CEO of Ford Motor Company recently highlighting 5,000 open mechanic jobs that pay more than $100,000 per year. And for datacenter operations, employers face shortages in hands-on infrastructure skills such as cabling, racking, and network hardware.

This problem is exacerbated by the demographics of an aging workforce and a decades-old policy trend of deprioritizing vocational education for young Americans. A generation of skilled workers, vocationally trained in high schools and apprenticeships in the 20^th century, are retiring from the trades. In the first quarter-century of the 21^st century, high schools pivoted towards preparing young people for higher education and advanced degrees, often at the expense of traditional shop classes and training in skilled craftsmanship.

The increased demand for skilled trades, paired with an aging workforce, requires an enhanced public-private workforce partnership. Secondary schools in the US can be incentivized to do more to educate young people about the trades through vocational schools and pre-apprenticeship programs. Registered apprenticeship programs offered nationally provide a fulfilling career path with long-term wages and benefits.

In partnership with labor, the federal government can champion a national apprenticeship and workforce development initiative that helps young and aspiring American workers near AI infrastructure projects, especially in rural and post-industrial regions. President Trump’s AI Action Plan rightly identifies this opportunity, and we will work closely with the Department of Labor to help scale this effort. The federal government can also help by streamlining the process by which businesses can establish and maintain a registered apprenticeship program. They can also maximize the use of existing federal dollars that directly support registered apprenticeship programs. This could entail modernizing the regulations for the National Apprenticeship Act or updating the statutory language itself.

4.We will add to the tax base for your local hospitals, schools, parks, and libraries.

One of the most tangible benefits from datacenter development is invisible to an individual driving nearby. It’s the property taxes paid by datacenters to the local municipality, which are substantial. But this too requires that the private sector take a responsible approach, as described below.

We won’t ask local municipalities to reduce their local property tax rates when we buy land or propose a datacenter presence. Instead, we’ll pay our full and fair share of local property taxes, adding revenue to local towns and cities. This is obviously critical to supporting the growth a local community often experiences when datacenters are built or expanded. And most importantly, at a time when many communities are facing revenue shortages that threaten vital public assets like hospitals, schools, parks, and libraries, we know from experience that this can make a big difference.

The benefits of this approach are nowhere more apparent than in Quincy, Washington, a small agricultural community about 150 miles east of Seattle where Microsoft built its first datacenter in 2008. Since then, we have built more than twenty datacenters in the area, providing ongoing employment to thousands of construction workers for almost two decades. Hundreds of technicians enjoy permanent jobs in those datacenters, earning salaries well above the median income for Quincy. And we estimate that for every direct construction job created, another one is created in related sectors, including security services, maintenance and repair, retail, restaurants, and more. Altogether, our datacenters drive more than $200 million in regional economic activity each year.

As a result, the share of Quincy residents living below the poverty line has been cut in half, dropping from 29.4 percent in 2013 to 13.1 percent in 2023. And county property tax revenues have more than tripled over the past two decades, from roughly $60 million to more than $180 million. This has enabled the city to invest in public services and amenities. Last year, as rural hospitals around the country cut back on critical care offerings and shuttered their doors, Quincy opened a new 54,000-square-foot medical center. The city has also made substantial renovations to its high school, adding state-of-the-art athletic facilities, an auditorium, and a career and technical training department.

We want to make sure that the other communities where our datacenters are located benefit from our presence in the same way. In all the regions where we build, own, and operate datacenters, we’re devoted to taking a civically responsible approach. This means recognizing the importance of civic services, including public safety, local healthcare, schools, libraries, and parks. As we become an important local employer, local communities can count on us to be a constructive contributor to local business and civic efforts.

5. We’ll strengthen your community by investing in local AI training and nonprofits.

We believe the datacenter communities that power AI should be among the first to benefit from it. As these communities help drive innovation and economic growth for the nation, it’s essential that they share in the economic, educational, and community benefits AI is creating. Especially as jobs evolve and require more AI skills, this requires local investments in AI education and training. To support this goal, we will provide free, age-appropriate, best-in-class AI training and education in these communities in partnership with trusted, local community-based organizations.

For years, we have been helping people gain essential digital skills in communities in and around our datacenters, such as Quincy in Eastern Washington, Boydton in Southern Virginia, and Mt. Pleasant in Southeast Wisconsin. One thing we’ve learned is that these communities have vibrant anchor institutions—schools, libraries, and local chambers of commerce—that form the backbone of local learning, workforce development, and economic growth. That’s why our approach as we go forward will be to invest in communities with our datacenters to partner with and provide support to these anchor institutions so that every community member can leverage the power of AI in how they live, work, and learn.

First, we will partner with local K-12 schools, community colleges, and universities to provide age-appropriate, responsible AI literacy training and learning experiences for students and teachers in our datacenter communities. This will build on some of our most recent experiences. For example, in Quincy, Washington, we partnered with Quincy High School and the local FFA chapter to teach students the critical AI and data skills needed for careers in precision agriculture. And in our datacenter region in Mt. Pleasant, Wisconsin, we recently launched an AI bootcamp for students and faculty with Gateway Technical College to cultivate a new generation of developers and creators of AI tools and technology across Wisconsin technical colleges.

Our commitment is to build on this work to help students and teachers responsibly and effectively engage with AI, create with AI, manage AI, and design with AI by bringing free, locally relevant, responsible AI training that is aligned with AI literacy standards to students in every K-12 school, community college, and university in our datacenter markets.

Second, we will support adults in our datacenter communities with AI tools and skills by creating neighborhood AI learning hubs in partnership with local libraries in our key datacenter markets. This approach will build upon our previous digital skilling partnerships with local libraries. For example, during COVID, we partnered with libraries in rural communities across the country, and more recently, we helped train libraries in our Quincy and Mt. Pleasant datacenter markets on AI so that they could help their patrons learn AI skills. Building on this work, we will invest in AI literacy skills development for librarians and provide access to free AI literacy training and certifications to local library patrons, including by equipping public terminals at local libraries in our datacenter regions with AI tools and services.

Third, we will support AI skills training for small businesses. We recognize that AI training will be critical for small businesses as they navigate the transition to the AI economy. These businesses are the backbone of local economies, and their success directly impacts job creation, workforce stability, and community vitality. Through a new workforce transformation initiative, we will deliver AI training, tools, and insights to local chambers of commerce that support these small businesses. We will also provide flexible grants for AI training and upskilling to local chambers of commerce and a variety of workforce organizations to help local businesses upskill employees, adopt AI responsibly, and prepare their workforce for ongoing transformation—ensuring that economic opportunity stays rooted in the communities where we build and operate datacenters.

Finally, we will invest in your local nonprofit community. A defining aspect of Microsoft’s own history and culture has long been a commitment to support the many nonprofit organizations that are vital to every community the company calls home. As we expand our datacenters in new communities, we’re committed to bringing this role to these new regions.

This starts with support for our employees in the local community. We provide two key benefits to all our full-time employees. First, we will match every hour they spend volunteering for a nonprofit with a donation to that group of $25. Second, we’ll match each dollar they donate to a nonprofit with an equal donation by Microsoft. These give all our employees, including in our datacenters, a total potential match of $15,000 each year.

This approach to community engagement is an important part of Microsoft’s culture, and it has become the largest nonprofit charitable matching program in the history of business. In 2024 in the United States, it raised $229.1 million in donations for 29,000 nonprofits, plus 964,000 volunteer hours contributed by our employees. It’s a part of Microsoft we’re excited to bring to the communities that have our datacenters.

We recognize that our support for the local community also needs to go beyond this type of program. Our broader contribution must start with listening. You know best what your town needs, what nonprofits are making a difference, and which organizations are best positioned to do more. We will provide locally based Microsoft liaisons in major US datacenter communities to work side by side with local leaders and nonprofits. Our local staff will provide a community connection to our various Microsoft teams and resources. Working together, we will shape our direction and connection to help further our support for local nonprofits.

Conclusion

Many lessons emerge from the nation’s 250-year history relating to technology and infrastructure. The first is that large-scale infrastructure expansion is vital to economic growth and everyday improvements in people’s lives. Our lives today rely on electrical appliances, automobiles, phones, airplanes, and much more that would be impossible without modern infrastructure.

But a second lesson illustrates an important tension. Major infrastructure expansion is always difficult. It’s expensive. It inevitably raises questions, concerns, and even controversies. This has been true for more than 200 years, and we should assume it will be true well into the future. This always requires that important decisions be made by government leaders from village presidents and town councils to the American President and Congress.

Third, the most important decisions are often made at the local level. This reflects the outsized impact—both positive and negative—of infrastructure expansion at the local level. It also reflects the American political tradition and our zoning and permitting laws, which rightly put decision-making authority closest to those elected to serve local communities.

There’s a final lesson that speaks most directly to us. Private companies can help by stepping up and acting in a responsible way. We cannot surmount inevitable community challenges by ourselves. But we can make everything easier by embracing a long-term vision. By recognizing our responsibility. By playing a constructive role. And by supporting the entire community.

As we look to the future, we are committing to taking this final lesson to heart. And making it a fundamental part of our efforts every day.

[1] News Releases | ABC: Construction Industry Must Attract 439,000 W

 

The post Building Community-First AI Infrastructure appeared first on Microsoft On the Issues.

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Remember the Ashley Madison data breach? That was now more than a decade ago, yet it arguably remains the single most noteworthy data breach of all time. There are many reasons for this accolade, but chief among them is that by virtue of the site being expressly designed to facilitate extramarital affairs, there was massive social stigma attached to it. As a result, we saw some pretty crazy stuff:

1. Various websites were stood up to publicly disclose the presence of people in the data and out them as “cheaters”
2. Churches trawled through the data and contacted the spouses of exposed parishioners
3. The media outed noteworthy individuals they searched for in the breach
4. A radio station back home in Australia encouraged listeners to dial in to check if their spouse was in the data

Arguably, we now live in a more privacy-conscious era, one full of acronyms such as GDPR and CCPA, among others, in different parts of the world. The right to be forgotten, the right to erasure, and, indeed, privacy as a fundamental human right feature very differently in 2026 than they did in 2015. But arguably, even back then, the impact of outing someone as a member of the site should have been obvious. It was certainly obvious to me, which is why I introduced the concept of a sensitive data breach before the data even went public. HIBP wouldn’t show results for this breach publicly because I was concerned about the impact on people being outed. My worst fear was a spouse coming home to find someone having taken their own life, an HIBP search result on the screen in front of their lifeless body.

People died as a result of the breach. Marriages ended and lives were turned upside down. People lost their jobs. The human toll of the breach was profound. The decision I made after witnessing this was that if a breach was likely to have serious personal or social consequences for people in there, it would be flagged as sensitive and not publicly searchable.

The public doxing of members of the service was often justified on a moral basis: “adultery is bad, they deserve to be outed”. But there are two massive problems with this attitude, and I’ll begin with the purpose for which accounts were sometimes made:

An email address appearing in that breach implied that the person was there to have an extramarital affair because that was literally the catch-phrase of the service: “Life is short, have an affair”. But the reality was that people were members of the service for many, many different reasons. Have a read of my post titled Here’s What Ashley Madison Members Have Told Me and you’ll begin to understand how much more nuanced the situation was:

1. Single people had joined the service, and later married before the breach occurred
2. People who were worried about a cheating spouse joined the service in order to try to catch them
3. Accounts were made with some people’s names and email addresses without their consent (there are many “Barrack Obamas” in the data)

So, should everyone with an email address on Ashley Madison be considered an adulterer? Clearly, no, that completely misses the nuances of what an email address in a data breach really means. But what about the people who were there to have an affair? Well, that brings us to the second problem:

Our own personal belief systems are not a valid basis for outing people publicly because their belief systems differ. I used more generic terms than “extramarital affair” or “cheating” because there are many other data breaches that are flagged as sensitive in HIBP for the very same reason. Fur Affinity, for example: there is a social stigma around furries and outing someone as a member of that community could have negative consequences for them. Rosebutt Board is another example: anal fisting is evidently something a bunch of people are into, and equally, I’m sure there are many who take a moral objection to it. And finally, to get to the catalyst for this post, WhiteDate: the website that is ostensibly designed for white people to date other white people. Flagging that as sensitive resulted in some unsavoury commentary being directed at me:

U are a Nazi end of story

— 𝔗𝔥𝔢ℑ𝔡𝔦𝔬𝔱 (@fuckelonsob) January 6, 2026

Now, I emphasised “ostensibly” because the more you dig into this breach, the more you find tones of white supremacy and other behaviours that definitely don’t align with my personal value system. That societal view doesn’t sit well with me, and I think I’m safe in saying it wouldn’t sit well with most people. Would someone being outed as a member of that service be likely to result in “serious personal or social consequences”? Yes, and you can see that in the messaging from the same account:

Context matters. U are literally shielding Nazi hate mongering scoundrels. We can't doxx white supremacists?

If ISIS had a dating site & it got breached, would you protect it out of fear of doxxing? No.

Every database leaked is sensitive in a way.

— 𝔗𝔥𝔢ℑ𝔡𝔦𝔬𝔱 (@fuckelonsob) January 6, 2026

This behaviour is precisely what I don’t want HIBP being used for: as a weapon to attack people solely on the basis of their email address being affiliated with a website that has had a data breach.

Imagine, for a moment, if ISIS did have a dating site and it was breached, should it be flagged as sensitive? Contrary to the comment about "every database leaked is sensitive", there is a clear legal definition for sensitive personal information and it includes:

personal data revealing racial or ethnic origin, political opinions, religious or philosophical beliefs;

trade-union membership;

genetic data, biometric data processed solely to identify a human being;

health-related data;

data concerning a person’s sex life or sexual orientation.

An ISIS dating website breach would tick many of the boxes above and would therefore constitute a sensitive data breach. That's not an endorsement of what they stand for; it's simply a data-processing decision. But there may be a nuance in there which I didn't see present in the WhiteDate data - what if it contained illegal activity? (Sidenote: for the most part, HIBP is used by people in Western Europe, North America and Australasia, so when I say "illegal", I'm looking at it through that lens. Clearly, there are parts of the world where our "illegal" is their "normal", which further complicates how I run a service accessible from every corner of the world.) I had another example recently that went well beyond moral contention and deep into the realm of illegality:

New sensitive breach: "AI girlfriend" site Muah[.]ai had 1.9M email addresses breached last month. Data included AI prompts describing desired images, many sexual in nature and many describing child exploitation. 24% were already in @haveibeenpwned. More: https://t.co/NTXeQZFr2x

— Have I Been Pwned (@haveibeenpwned) October 8, 2024

Of all the different things people can disagree on when it comes to our moral compasses, paedophilia is where we unanimously draw the line. But I still flagged it as sensitive because of the reasons outlined above. Many people using the service were just lonely guys trying to create an AI girlfriend with no prompts around age. There would be email addresses in there that weren’t entered by the rightful owner. And then, there are cases like this:

That's a firstname.lastname Gmail address. Drop it into Outlook and it automatically matches the owner. It has his name, his job title, the company he works for and his professional photo, all matched to that AI prompt. pic.twitter.com/wpXQMBLf3B

— Troy Hunt (@troyhunt) October 9, 2024

I sat there with my wife, looking at the LinkedIn profile that used the same email address as the person who posted that comment. We looked at his photo and at the veneer of professionalism that surrounded him on that site, knowing what he had written in that prompt above. It was repulsive. Further, beyond being solely an affront to our morals, it was clearly illegal. So, I had many conversations with law enforcement agencies around the world and ensured they had access to the data. Involving law enforcement where data sets contain illegal activity is absolutely the right approach here, but equally, not being the vehicle for implying someone’s affiliation or beliefs and doxing them publicly without due process is also absolutely the right approach.

I understand the gut reaction that flagging a breach like WhiteDate as sensitive protects people whom most of us do not like. But a dozen years of running this service have caused me to consider individual privacy and rights literally hundreds of times, and these conclusions aren’t arrived at hastily. Imagine for a moment, the possible ramifications for HIBP if the service were used to publicly shame someone as a "Nazi" and that, in turn, had serious real-world consequences for them. Whether that implication was right or not, there are potentially serious ramifications for us that could well leave us unable to operate at all. And, as the Ashley Madison examples show, there are also potentially life-threatening outcomes for individuals.

I don't particularly care about one random, anonymous X account making poorly thought-out statements, but the same sentiment has been expressed after loading previous similar breaches, and it deserves a blog post. Equally, I've written before about why all the other data breaches are publicly searchable and again, that conclusion is not arrived at lightly.

I’ll finish with a note about privacy that relates to my earlier comment about it being a human right. It's literally a human right under Article 12 of the Universal Declaration of Human Rights:

No one shall be subjected to arbitrary interference with his privacy, family, home or correspondence, nor to attacks upon his honour and reputation. Everyone has the right to the protection of the law against such interference or attacks.

Breaches with legally defined sensitive data will continue to be flagged as sensitive, and breaches with illegal data will continue to be forwarded to law enforcement agencies.

Throughout 2025, I spoke a few times about our home energy solution, including our grid usage, our solar array and our Tesla Powerwall batteries. Now that I have a full year of data, I wanted to take a look at exactly how everything is working out, and, in alignment with our objectives, how much money we've saved!

Our setup

Just to give a quick overview of what we're working with, here are the details on our solar, battery and tariff situation:

• ☀️Solar Panels: We have 14x Perlight solar panels managed by Enphase that make up the 4.2kWp array on our roof, and they produce energy when the sun shines, which isn't as often as I'd like in the UK!
• 🔋Tesla Powerwalls: We have 3x Tesla Powerwall 2 in our garage that were purchased to help us load-shift our energy usage. Electricity is very expensive in the UK and moving from peak usage which is 05:30 to 23:30 at ~£0.28/kWh, to off-peak usage, which is 23:30 - 05:30 at ~£0.07/kWh, is a significant cost saving.
• 💡Smart Tariff: My wife and I both drive electric cars and our electricity provider, Octopus Energy, has a Smart Charging tariff. If we plug in one of our cars, and cheap electricity is available, they will activate the charger and allow us to use the off-peak rate, even at peak times.

Now that we have some basic info, let's get into the details!

Grid Import

I have 3 sources of data for our grid import, and all of them align pretty well in terms of their measurements. I have the amount our electricity supplier charged us for, I have my own CT Clamp going via a Shelly EM that feeds in to Home Assistant, and I have the Tesla Gateway which controls all grid import into our home.

Starting with my Home Assistant data, these are the relevant readings.

Jan 1st 2025 - 15,106.10 kWh
Dec 31st 2025 - 36,680.90 kWh
Total: 21,574.80 kWh
Total Import: 21.6 MWh

As you can see in the graph, during the summer months we have slightly lower grid usage and the graph line climbs at a lower rate, but overall, we have pretty consistent usage. Looking at what our energy supplier charged, us for, that comes in slightly lower.

Total Import: 20.1 MWh

I'm going to use the figure provided by our energy supplier in my calculations because their equipment is likely more accurate than mine, and also, what they're charging me is the ultimate thing that matters. The final source is our Tesla Gateway, which shows us having imported 21.0 MWh.

It's great to see how all of these sources of data align so poorly! 😅

Grid Export

Looking at our export, the graph tells a slightly different story because, as you can see, we didn't really start exporting properly until June, when our export tariff was activated. Prior to June, it simply wasn't worth exporting as we were only getting £0.04/kWh but at the end of May, our export tariff went live and we were then getting paid £0.15/kWh for export. My first and second blog posts cover the full details of this change when it happened if you'd like to read them but for now, just note that it will change the calculations a little later as we only had export for 60% of the year.

Total Export: 6.0 MWh

With our grid export covered the final piece of the puzzle is to look at our solar.

Solar Production

We're really not in the best part of the world for generating solar power, but we've still managed to produce quite a bit of power. Even in the most ideal, perfect scenario, our solar array can only generate 4.2kW of power, and we're definitely never getting near that. Our peak production was 2.841kW on 8th July at 13:00, and you can see our full annual production graph here.

Looking at the total energy production for the entire array, you can see it pick up through the sunnier months but remain quite flat during the darker days of the year.

Jan 1st 2025 - 2.709 MWh
Dec 31st 2025 - 5.874 MWh
Solar Production: 3.2 MWh

Just to confirm, I also took a look at the Enphase app, which is drawing it's data from the same source to be fair, and it agrees with the 3.2 MWh of generation.

Calculating the savings

This isn't exactly straightforward because of the combination of our solar array and excess import/export due to the batteries, but here are the numbers I'm currently working on.

Total Import: 20.1 MWh
Total Export: 6.0 MWh
Solar Production: 3.2 MWh

That gives us a total household usage of 17.3 MWh.

(20.1 MWh import + 3.2 MWh solar) − 6.0 MWh export = 17.3 MWh usage

If we didn't have the solar array providing power, the full 17.3 MWh of consumption would have been chargeable from our provider. If we had only the solar and no battery, assuming a perfect ability to utilise our solar generation, only 14.1 MWh of our usage would need to be imported. The cost of those units of solar generation can be viewed at the peak and off-peak rates as follows.

Peak rate: 3,200 kWh x £0.28/kWh = £896
Off-peak rate: 3,200 kWh x £0.07/kWh = £224

Given that solar panels only produce during peak electricity rates, it would be reasonable to use the higher price here. A consideration for us though is that we do have batteries, and we're able to load-shift all of our usage into the off-peak rate, so arguably the solar panels only made £224 of electricity.

The bigger savings come when we start to look at the cost of the grid import. Assuming we had no solar panels, we'd have imported 17.3 MWh of electricity, and with the solar panels and perfect utilisation, we'd have imported 14.1 MWh of electricity. That's quite a lot of electricity and calculating the different costs of peak vs. off-peak by using batteries to load shift our usage gives some quite impressive results.

Peak rate: 17,300 kWh x £0.28/kWh = £4,844
Peak rate with solar: 14,100 kWh x £0.28 = £3,948

Off-peak rate: 17,300 kWh x £0.07/kWh = £1,211
Off-peak rate with solar: 14,100 kWh x £0.07/kWh = £987

This means there's a potential swing from £4,844 down to £987 with solar and battery, a total potential saving of £3,857!

This also tracks if we look at our monthly spend on electricity which went from £350-£400 per month down to £50-£100 per month depending on the time of year. But it gets better.

Exporting excess energy

Our solar array generates almost nothing in the winter months so our batteries are sized to allow for a full day of usage with basically no solar support. We can go from the start of the peak rate at 05:30 all the way to the off-peak rate at 23:30 without using any grid power. When it comes to the summer months, though, our solar array is producing a lot of power and we clearly have a capability to export a lot more. The batteries can fill up on the off-peak rate overnight at £0.07/kWh, and then export it during the peak rate for £0.15/kWh, meaning any excess solar production or battery capacity can be exported for a reasonable amount.

If we take a look at the billing information from our energy supplier, we can see that during July, our best month for solar production, we exported a lot of energy. We exported so much energy that it actually fully offset our electricity costs and allowed us to go negative, meaning we were earning money back.

Here is our electricity import data:

And here is our electricity export data:

That's a pretty epic scenario, despite us being such high energy consumers, to still have the ability to full cover our costs and even earn something back! For clarity, we will still have the standing charge component of our bill, which is £0.45/day so about £13.50 per month to go on any given month, but looking at the raw energy costs, it's impressive.

The final calculation

I pulled all of our charges for electricity in 2025 to see just how close my calculations were and to double check everything I was thinking. Earlier, I gave these figures:

Off-peak rate: 17,300 kWh x £0.07/kWh = £1,211

If 100% of our electricity usage was at the off-peak rate, we should have paid £1,211 for the year. Adding up all of our monthly charges, our total for the year was £1,608.11 all in, but we need to subtract our standing charge from that.

Total cost = £1,608.11 - (365 * £0.45)
Total import = £1,443.86

This means that we got almost all of our usage at the off-peak rate which is an awesome achievement! After the charges for electricity, I then tallied up all of our payments for export.

Total export = £886.49

Another pretty impressive achievement, earning so much in export, which also helps to bring our net electricity cost in 2025 to £557.37! To put this another way, the effective rate of our electricity is now just £0.03/kWh.

£557.37 / 17,300kWh = £0.03/kWh

But was it all worth it?

That's a tricky question to answer, and everyone will have different objectives and desired outcomes, but ours was pretty clear. Running two Electric Vehicles, having two adults working from home full time, me having servers and equipment at home, along with a power hungry hot tub, we were spending too much per month in electricity alone, and our goal was to reduce that.

Of course, it only makes sense to spend money reducing our costs if we reduce them enough to pay back the investment in the long term, and things are looking good so far. Here are the costs for our installations:

£17,580 - Powerwalls #1 and #2 installed.
£13,940 - Solar array installed.
£7,840 - Powerwall #3 installed.
Total cost = £39,360

If we assume even a generous 2/3 - 1/3 split between peak and off-peak usage, with no Powerwalls or solar array, our electricity costs for 2025 would have been £3,632.86:

11,533 kWh x £0.28/kWh = £3,229.24
5,766 kWh x £0.07/kWh = £403.62
Total = £3,632.86

Instead, our costs were only £557.37, meaning we saved £3,078.49 this year. We also only had export capabilities for 7 months of 2025, so in 2026 when we will have 12 months of export capabilities, we should further reduce our costs. I anticipate that in 2026 our electricity costs for the year will be ~£0, and that's our goal.

Having our full costs returned in ~11 years is definitely something we're happy with, and we've also had protection against several power outages in our area along the way, which is a very nice bonus. Another way to look at this is that the investment is returning ~9%/year.

Year	Cumulative savings (£)	ROI (%)
1	3,632.86	9.23%
2	7,265.72	18.46%
3	10,898.58	27.69%
4	14,531.44	36.92%
5	18,164.30	46.15%
6	21,797.16	55.38%
7	25,430.02	64.61%
8	29,062.88	73.84%
9	32,695.74	83.07%
10	36,328.60	92.30%
15	54,492.90	138.43%
20	72,657.20	184.61%
25	90,821.50	230.76%

Of course, at some point during that period, the effective value of the installation will reduce to almost £0, and we have to consider that, but it's doing pretty darn good. If we hadn't needed to add that third Powerwall, this would have been so much better too. We'll see what the future holds, but with the inevitable and continued rise of energy costs, and talk of moving the standing charge on to our unit rate, things might look even better in the future.

Onwards to 2026!

Now that we have everything properly set up, and I'm happy with all of our Home Assistant automations, we're going to see how 2026 goes. I will definitely circle back in a year from now and see how the numbers played out, and until then, I hope the information here has been useful or interesting 👍

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