Strategy and Best Practices
Article | July 8, 2022
A high-tech greenhouse comprised mainly of solar glass generating electricity to help run it was officially opened yesterday in Western Australia.
ClearVue Technologies Limited’s solar glass involves a nanoparticle interlayer and spectral-selective coating on the rear external surface that enables 70% of natural light to pass through while redirecting infrared and UV light converted to infrared to the edge where it is harvested by solar cells. ClearVue says each 1m2 of its window product is currently rated to generate 30 watts-peak of electric power, but also mentions a new-generation product with the proven ability to generate 40 watts peak per m2 to be available sometime this year.
Article | July 7, 2023
Machine learning and artificial intelligence (AI) are two of the most commonly used commercial phrases these days. As a result, companies across sectors are searching for methods to include them in order to optimize and automate their key operations. The energy sector is no exception!
Indeed, throughout the years, renewable energy industries (wind, solar, hydro, nuclear) have substantially gained from the potential of machine learning. They were able to reduce their expenses, make better projections, and raise the rate of return on their portfolio. And this tendency is just going to gain momentum. If your company is in the energy industry or utilizes a lot of power, machine learning and AI can help you improve your business performance. But how precisely? Let's get started.
Ways in Which AI and Machine Learning are Changing Energy Sector
There are a few methods that machine learning and AI can be applied to positively improve the energy industry. Here are a few popular applications currently under development.
AI helps match energy output with demand and ensure power grid stability and resilience.In 2003, a low-hanging high-voltage electricity line hit an overgrown tree in Ohio, causing a widespread blackout. There was no power system alarm and no sign of the incident. The electric company didn't notice until three additional power lines failed. This carelessness ultimately brought down the whole grid. The 50 million-person blackout lasted two days. Eleven individuals died, and $6 billion was lost.
Predictive maintenance can be implemented using machine learning and IoT
Sensors gather operational time series data from electricity lines, equipment, and stations (data accompanied by a timestamp).
Machine learning algorithms can then forecast when a component will fail (or n-steps). It can also anticipate machinery's remaining usable life or future breakdown. These algorithms detect machine failure, eliminate blackouts or downtimes, improve maintenance procedures, and reduce maintenance expenses.
Grid management is a promising AI application in energy. Complex networks distribute electricity to users (also known as the power grid). Generation and demand must always match in the electrical system. Other issues, like blackouts and system breakdowns, can occur.
Despite being ancient, pumped hydroelectric storage is the most common way to store energy. It operates by moving water upwards and letting it fall into turbines. Renewable energy makes predicting the grid's power generation challenging. After all, it is affected by a variety of things, like sunlight and wind.
Large demand shifts can be expensive for nations that depend on renewable energy. As nations migrate to green energy, it's harder to adapt to demand fluctuations. Germany plans to use 80% renewable energy by 2050.
Countries such as Germany will encounter two major challenges Demand fluctuations: On some days or times of the year, power consumption soars (on Christmas, for example) Weather volatility: Without wind or clear skies, it might be hard to meet electrical demand. In both circumstances, more stations or fossil fuel-powered facilities must meet demand
Solving demand response issues
Many nations are partnering with businesses to examine weather forecasts, power demand, etc. Germany's EWeLiNE project forecasts wind and solar energy at a specific moment. This enables the government to use non-renewable energy to meet additional power demand.
They utilize enormous historical data sets to train machine learning algorithms, as well as data from wind turbines or solar panels, to properly balance supply and demand.
AI increases the potential of humans. Several renewable energy producers are investing in artificial intelligence to boost their businesses.There are numerous uses of artificial intelligence in renewable energy. The fundamental purpose of AI integrated systems is to reduce forecasting issues and incorporate renewable energy into the central energy grid as effectively as possible. AI can also assist renewable energy providers in developing successful plans and policies based on present energy consumption and demand.
Strategy and Best Practices, Energy
Article | July 27, 2022
“With Great Power Comes Great Responsibility”
– Voltaire (François-Marie Arouet)
We, humans, had completely buried this quote until it was brought back to life recently. Business leaders should remember this quote as it perfectly fits into the environmental-business perspective that we are presently facing.
If the world has to tackle the problem of climate change or come even close to achieving that goal, businesses and industries will have to play a key role. Almost a quarter, or 23% to be precise, of greenhouse gas emissions in the United States, come directly from industries. This number rises to 29.6% if we combine indirect emissions too.
When looking for causes of climate change, the private sector is often linked to. Minimizing your carbon footprint appears to be the year's buzzword, but where can businesses begin with such an ambiguous task? How do we assess progress? Peter Drucker wrote the premise of an answer back in 1954: "What gets measured, gets managed."
If a business really wants to become more sustainable, the first step should be to try to understand its current situation and begin tracking its carbon emissions. Measuring carbon emissions is a difficult problem. Major businesses that do not have carbon monitoring and reduction programs have become the exception.
Recognizing and measuring CO2 emissions aids in the identification of excessive energy consumption and other inefficiencies. Most of the time, lowering greenhouse gas emissions goes hand in hand with making a business's processes more efficient and cost-effective.
Reducing Greenhouse Gas Emissions: What Do Businesses Gain?
In addition to the long-term environmental benefits that will help us in saving our planet, organizations can also benefit from the positive impacts of greenhouse gas emission reduction. Some of the top benefits of effective emission management are as follows.
When it comes to cost reductions, simply minimizing your energy consumption reduces both your organization's carbon footprint and its operating expenses. According to a 2016 Energy Star report, the owner of Kimberly-Clark Berkley Mill invested $350,000, which generated yearly savings of $160,000 and a rapid return on investment (ROI) of just over one and a half years when LED lighting was installed to replace the fluorescent and HID lighting that was traditionally used.
With a 20-fold rise in global climate change regulations since 1997, securing proactive regulatory compliance is much more important than ever in the minds of corporate leadership, public spheres, and stakeholders – and it's only becoming more important. Adopting an effective greenhouse gas emission reduction program, as well as tracking and reporting on progress, is essential for businesses to adopt in order to maintain operations and avoid penalties.
Improved External Relations
Consumer spending power has an enormous impact on the process of shaping organizational action. In the eyes of the public, the process of committing to responsibility in the domains of broader sustainability and greenhouse gas emissions reduction is a significant credibility boost. When your company takes proactive steps to reduce carbon dioxide and greenhouse gas emissions, the resulting increase in the quality and depth of relationships with potential partners and external business connections is priceless.
Enhanced Stakeholder Relationships
Along with a stronger relationship with the audience, the influence of transparent sustainability indicators and performance has the potential to strengthen crucial relationships with stakeholders. More investors than ever are shifting capital away from carbon-heavy, secretive businesses and toward companies that have decided to be open, proactive, and honest regarding their greenhouse gas emissions management within the sustainability world and beyond. Emission Sources Defined in Business Operations Within a business's operation chain, emission sources are classified into three categories. These scopes are established so that businesses can trace the source of their greenhouse gas emissions and modify their operations to minimize their carbon footprint.
Emission scope is defined as follows:
Scope 1 Emission
Scope 1 emissions are directly caused by business operations. Organizations with fossil fuel-burning vehicle fleets, for example, are directly liable for carbon emissions by burning those fossil fuels.
Scope 2 Emission
Scope 2 emissions are caused by an organization purchasing energy (e.g., electricity, heat, or air conditioning) produced by a process that emits greenhouse gases. A scope 2 emission is, for example, electricity generated by burning coal that a business later purchases. Because the company consumes this energy, they must record the emissions generated when it was generated.
Scope 3 Emissions
Scope 3 emissions are not caused by a company's direct activities. Other entities in a company's value chain are responsible for these emissions. Scope 3 emissions for one organization could be scope 1 and 2 emissions for another. A company that manufactures products, for example, would have scope 3 emissions from a company that eventually disposes of those items. Scope 3 is responsible for most of a company's emissions, accounting for 65% to 95% of a company's carbon footprint. Currently, reporting scope 3 emissions is optional for businesses. Organizations must, however, start tracking their scope 3 emissions since this is where tremendous reductions in carbon emissions can occur.
How Are Large Enterprises Measuring and Reducing Their Carbon Footprints?
Larger enterprises, like Apple and ExxonMobil, have begun to provide scope 3 emissions data. Other companies are collaborating with their supply chain to build collaborative initiatives among companies to report these emissions. Businesses have begun to cooperate even outside of supply chains. Competitors in the same industry have started to form partnerships to solve the issue of measuring their carbon footprints. Because these organizations often share manufacturers and suppliers, they have decided to deal with the issue together.
Other businesses manage environmental sustainability in a different manner.Enterprises in the agriculture industry have pledged to reduce greenhouse gas emissions, recycle, and provide resources and information to smaller agricultural organizations wanting to go green.Many of the world’s leading auto manufacturers help by producing vehicles that are more environmentally friendly and have the better fuel economy. Others are creating alternative-fuel cars or investing in sustainable energy projects.
The major retailers, manufacturers, and software companies have all made efforts to reduce their carbon footprint in different ways. Many multinational enterprises are adopting more sustainable business practices, such as using renewable energy and recycled materials in product manufacturing.
How Can Small Businesses Seek Help Measuring Their Carbon Footprints?
For the time being, many small businesses are finding it difficult to gather data on all these emissions that are beyond their control. According to the BBC, only 10% of more than 1,000 organizations surveyed in the United Kingdom keep track of their carbon footprint. Moreover, one in every five companies does not understand what the term "net-zero" means and a third really hasn't sought any help to make their company more sustainable. Exploring available information on measuring emissions data is the best approach for small businesses to understand more about the ways they can reduce their carbon footprint. The EPA Center for Corporate Climate Leadership includes a wealth of resources to assist small business owners in measuring and reporting their emissions. Business owners can learn how to establish a greenhouse gas inventory, measure their emissions, collaborate with sustainable suppliers, and gather data to develop sustainable solutions.
Small businesses can also utilize a carbon footprint calculator to determine the quantity of emissions generated by their activities. Once company owners realize how much carbon they are emitting, they can start to tackle where it is coming from and make the necessary modifications. The most important thing that business owners can do is to always look for ways to improve their business's sustainability. Additional information will be made available to help company owners as they seek guidance on how to minimize their carbon footprint.
Best Practices for Companies to Achieve Net Zero and Stay Profitable
Transitioning to net zero is such a demanding task that many businesses believe it is impossible to do while retaining profit margins. As a result, many businesses concentrate on low-hanging fruit and short-term alternatives, like offloading emissions onto others by divesting from high-carbon-emitting companies. Businesses, on the other hand, can start by creating a greenhouse gas inventory to monitor their carbon emissions. Here are just a few of the many ways we found that could help your business.
Cut Emissions Across the Whole Value Chain
For most businesses, the majority of emissions and the possibilities for climate action lie in "scope 3 assets". These aren't owned or managed by the reporting company, but they add to the business's value chain indirectly. Businesses must take action on scope 3 emissions in order to successfully cut emissions.
Use Sustainable Web Hosting Services
Hosting services are the silent consumers of fossil fuels. Until you host it yourself, your website is most certainly hosted on a data server in a warehouse that runs on fossil fuels. Data servers use a lot of energy since they have to be turned on and kept cool all the time. Renewable Energy Certificates are acquired by sustainable hosting providers in order to claim their renewable energy utilization.
Tackle the Root Causes
The areas of major emissions are often not the most effective sites for action. It is found that businesses are measuring emissions in order to determine underlying causes, either inside their own processes or anywhere in the value chain. Big tech businesses evaluate power efficiency down to the code level in their AI and cloud implementations and collaborate with chip manufacturers to reduce energy usage in the use of their products.
Don’t Automatically Defund High-Carbon Business
Investors are often enticed to enhance their portfolio of low-carbon activities merely by rearranging their capital allocation. However, when it comes to really incentivize reduction, a more effective technique is to engage in activities that presently generate high carbon emissions while giving out a clear and urgent roadmap to change. Some activists have realized this idea and are shifting their demands from divestment to a managed shift of high-carbon businesses.
Purchase Carbon Offsets
Carbon offsets are a type of trade. When you buy an offset, you are contributing to projects that decrease greenhouse gas emissions. A carbon calculator can help you calculate your travel carbon footprint and the monetary cost of those emissions. Remember that carbon offsets do not decrease the quantity of carbon in the atmosphere; rather, they serve as a balancing agent to neutralize the carbon emitted. Carbon offsets could be tax-deductible based on the company from whom you purchase them.
Many prominent brands, from Amazon to L'Oréal, have started to make significant investments in renewable energy and commitments to reduce emissions in their freight and logistics operations. Being mindful of how your activities contribute to greenhouse gas emissions can assist you in minimizing your carbon footprint. With the above-mentioned methods under your belt, you will be able to support the environment that we live in a while simultaneously pushing your organization to the next level of success. Don't miss the opportunity to get involved in energy-efficiency and sustainability initiatives for your company because the newest generation of consumers, millennials, have $2.45 trillion in spending power and are eager to spend more on brands that share their values of going green.
Frequently Asked Questions
What are scope 3 emissions?
The Greenhouse Gas Protocol Corporate Standard divides a company's greenhouse gas emissions into three "scopes." Scope 1 emissions are those emitted directly from owned or controlled sources. Scope 2 emissions are those caused by the production of bought energy. Scope 3 emissions encompass all indirect emissions (not included in scope 2) that happen in the reporting company's value chain, both in upstream and downstream emissions.
What are product life cycle emissions?
All emissions related to the production and utilize a single product, from the cradle to the grave, are referred to as the product life cycle emissions and include emissions from raw materials, manufacturing, transportation, storage, sale, usage, and disposal.
How can industries reduce global warming?
By implementing passive or sustainable energy-based heating and cooling systems, increasing energy efficiency, and solving other important concerns such as methane leaks, the industry can cut its emissions by 7.3 Gt per year. New food production technologies have the capability to cut emissions by 6.7 Gt per year
Article | December 23, 2021
Cleaner energy resources are the dire need of the hour and this is a known fact. While scientists and experts across the planet are striving hard to reduce our reliance on fossil fuels, our energy needs have never faced a downfall- thanks to rapid industrialization and urbanization. Although renewable resources like solar, wind, and hydro-electric power are the most popular alternatives, these are seasonal energy sources and the energy production from the same will not be similar all around the year. The fluctuations in production hence cannot always meet the energy demand of the population, and this makes the renewable energy sources not completely reliable.
Solar Production v/s Demand of the same in a year
What and How H2 is produced?
Now, this is where Hydrogen- the first element of the periodic table comes to the spotlight with a solution. Being a gas, hydrogen fuel can very well cater to our energy needs and is produced from techniques including Thermochemical, Solar-Water splitting, electrolytic and biological processes. While the production of this cleaner energy source leaves a carbon footprint of about 830 million tonnes in the form of CO2 annually, the result being a zero-emission fuel is what makes H2’s future bright.
Storage of H2 – the million-dollar question:
Having almost cleared the need and methods of producing hydrogen fuel, we will be looking at an area that is usually not given much thought about and that is the storage of H2. As already mentioned, for time being let us consider hydrogen as an alternative to renewable resources which is utilized when the energy demand increases drastically. While producing the fuel in the nick of time is obviously undoable, sufficient storage of H2 anticipating the demand is the best choice. Like Natural Gas, Hydrogen is also compressed before storing to achieve lower volume and also because liquid hydrogen demands a 64% higher amount of energy for storage than its compressed gaseous counterpart.
Storage tanks v/s Geological landforms:
Compressed Hydrogen can be stored in surface storage vessels (like steel composite concrete vessels and in wind turbine towers) or in geological landforms like (salt caverns, depleted O&G reservoirs, and aquifers). Nevertheless, unlike the underground geological landforms which offer huge storage capacity owing to their sheer scale, the storage tanks which can range in size from a small bottle to a huge tank require high amounts of pressure to store an appreciable amount of H2 in it. Since these storage tanks are usually constructed on the surface, the pressure conditions in these tanks need to be artificially stimulated and thereby mount huge upfront costs when compared to their geological storage counterpart.
H2 storage prices in Geological Landforms v/s Storage Vessels (in $/kg)
The above is a table comparing the prices of Hydrogen storage in Geological landforms and Storage Vessels at different pressure conditions. It is visible from the table that it's about 218 times cheaper to store the same amount of hydrogen in Geological landforms than in storage vessels.
Is geological storage truly a better option?
Like any other storage option geological storage too has its pros and cons. From the erosion of pipelines to the tedious task of injecting the gas and maintaining it at apt pressure conditions, geological storage has its limitations. However, the important prerequisite is the availability of the suitable landform itself.
While most of the Depleted O&G Reservoirs have already met all the requirements for a suitable Underground Hydrogen Storage (UHS) system, the presence of unrecoverable remnant fluids in it makes it both a boon and a bane. This is because the presence of remnant fluids like oil and gas satisfies the cushion gas need for efficient storage of H2 in the reservoir, chances of contamination of H2 by the same is also high. This is the reason why Aquifers too aren’t favorable underground landforms when it comes to hydrogen storage.
Salt Caverns- the best UHS System?
The problem of Hydrogen contamination in Depleted Oil & Gas reservoirs and aquifers leaves us to the next big suitable subsurface landform- salt caverns. Unlike the other two landforms, the problem of contamination can be prevented in these dome-like structures formed due to the upliftment of salt deposits and it is also found that about 98% of its storage efficiency can be used to store Hydrogen here. The reason behind its relatively expensive nature when compared to its other two counterparts is due to the process of salt removing or leaching that must be done before storing to ensure that the contamination of the gas is unheard of at least here.
Suitable Conditions of UHS:
As per Stefan Iglauer, the maximum amount of H2 can be stored at a depth of 1100m beneath the Earth’s surface and the capacity gradually decreases up until 3700 m depth beyond which the wettability of the gas increases as it percolates through the rocks and hence cannot be permanently immobilized. Conclusively it is found that suitable landforms formed at 1km depth can store up to 2.0 Mt of H2. Comparing this 2 MT storage capacity of Salt Caverns with the currently available storage tanks which can store about 800 kg of H2 in it, it is visible that geological landforms have a clear upper hand at least when it comes to storage capacity.
Future of UHS:
With demands for Hydrogen fuel estimated to grow at 5.48 % annually and the need for a suitable storage system of the same at 5.8% annually, the field of Underground Hydrogen Storage systems indeed has a bright scope. Moreover, to meet the large-scale needs of Industries, there is an imminent need to level up the storage capacity of H2 and by exploring suitable geological landforms across the globe, the estimated industrial need of 1200 kT/ year in 2050 can be met.