6 ways to reduce your personal carbon footprint

A carbon footprint is a measure of the greenhouse gases released into the environment in totality. This can be due to the actions of an individual or an organization. Here are some steps that help reduce carbon emissions while being at home. These steps are quick to implement and help one lead a more sustainable and eco-friendlier lifestyle in no time. The links between climate change and greenhouse gas emissions are too real to be ignored. The global temperatures are increasing, which is ultimately leading to unexpected and extreme weather conditions. It, therefore, becomes important to reduce the carbon footprint on an individualistic level, because the smallest of contributions matter.

1. In home insulation

Heating the household space is not only expensive but also energy intensive. By insulating certain areas in the house, heat can be retained during winters and also stay cool in the summers. It indicates a lesser use of energy and reduced carbon footprint.

2. Switching to renewables

Switching to renewable sources of energy like solar energy, not only saves money but also contributes to reduced household emissions.

3. Investing in energy efficient

It is important to invest in energy resources that are comparatively more efficient, be it appliances with a high star rating or simply energy-saving bulbs. Additionally, unplugging and switching off devices that are not in use helps make your home eco-friendly with a reduced carbon footprint.

4. Reducing the wastage of water

It takes a considerable amount of energy and resources to process and furthermore, deliver water to households. It is therefore important to not waste water and use it mindfully for a reduced carbon footprint.

5. Changing the dietary intake

The food that an individual consumes has an impact on the environment. For example, producing dairy and meat products emits greenhouse gases like methane. Choosing a diet that is plant-based contributes to a reduced personal carbon footprint.

6. Going digital

Sharing of documents and communicating via online methods or digitally, for example, trying to abstain from using paper-based documents and encouraging ongoing digital both in the personal and workspace is important.

Conclusion

Reducing carbon emissions can be achieved at home and even at the workplace. Whether it is making changes towards a more sustainable level on an individualistic level or on a societal level, at home or at the workplace, these contributions help reduce the carbon footprint.

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What differentiates carbon footprint from an ecological footprint?

An ecological footprint represents an effective comparison of the resources consumed by people in totality inclusive of the waste area and land that is required for the replacement of the resources. A carbon footprint also represents the usage of a resource but focuses mainly on the greenhouse gases that are released because of the burning of fossil fuels. The calculated greenhouse gas emissions make up only a small part of the ecological footprint, utilized in the same way as in the case of the carbon footprint. Both the calculations, however, rightfully illustrate the impact that the activities of human beings have on the environment.

The balance sheet (Global level)

The ecological footprint measures the range of demands that a population of humans have from the environment and nature as a whole. On the negative side are activities like energy usage that support the lives of humans. On the positive side, is the biocapacity of the earth which represents its ability to replace resources and effectively manage waste.

Climate and carbon

Greenhouse gas emissions from the burning of fuels can be absorbed by the Earth despite its ability to naturally replenish within the lifetime of a human. This is the reason why ecological footprints include the land area that is covered in forest and the area covered by sea required for the absorption of greenhouse gases like CO2. Carbon footprint on the other hand is measured in units of carbon dioxide or carbon equivalents, sans any reference to water or land area. A carbon footprint is primarily used to increase the amount of awareness that prevails with regard to the impact that greenhouse gases have on the environment.

The impact of carbon

The greenhouse gases that are quantitatively released in the atmosphere due to the burning of fossil fuels has a direct impact on the ecological footprint. A greater amount of greenhouse gases requires more land and sea area for the removal of these gases from the environment. More greenhouse gas emissions are proportional to a larger carbon footprint. The larger the carbon footprint, the larger the ecological footprint is going to be.

Deficit consumption

Human beings’ ecological footprint is greater than the earth’s biocapacity since the mid-1980s. The balance sheet has therefore been a deficit, with the difference taken out by drawing on the fossil fuels (stored resources) that the Earth is unable to replace each year.

Conclusion

At C6 Energy, a sustainable environment is a part of our purpose. Our Graphene enabled cell technology is carbon neutral and has a zero carbon footprint.

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How does waste management help businesses reduce carbon footprint?

Recycling waste, reducing it and responsibly disposing it is becoming greatly prevalent in the present-day time because of global warming and with landfills becoming a concern on a worldwide basis. We as individuals or as businesses can and must contribute our bit in order to reduce the impact of the waste generated. However, prior to this, it is important to be aware of the personal carbon footprint. Carbon footprint is the amount of carbon emissions in the atmosphere as a result of the activities of an individual or an organisation. The ultimate goal today must be to transform into becoming carbon neutral, for the overall carbon output to either be reduced or be zero. However, this is not easy to achieve for businesses. It is therefore important to start from small steps, in order to rectify changes in climate and also focus on waste management.

Businesses have started to realise the importance of eco-considerations in order to compete better and attract greater business opportunities. Additionally, money can be saved with recycling of products. There are various other generally advertised considerations for carbon reduction such as adapting to a vegan diet or investing in E-vehicles. These are great considerations for an individual, however it is also important to consider the impact on a bigger scale. An approximate of 40 percent of greenhouse gases are emitted from the processes involving the manufacture, movement and discarding of used items. Adopting effective techniques for waste prevention and also responsibly recycling helps use lesser energy and reduce the GHG in the atmosphere for a better climate.

When the waste production is reduced and sustainable choices are made, lesser amount of energy is needed to support both manufacture and transportation in a business. Surprisingly, on recycling a single aluminium can, 95 percent of energy can be saved that would be utilised to produce a new can for new raw material. Carbon sequestration is proving to be a holy grail for the purpose of reducing the carbon footprint. In the same way, recycling paper allows a greater number of trees to stay standing that ultimately helps clean the greenhouse gas emissions from air and ultimately combat the ever-rising number of changes in the climate. It is a great step for homes as well businesses to quickly make a positive impact on the atmosphere because it is high time to act upon for diverting the tide of damage done in the past decades towards a positive direction. To conclude, it can be said that waste management strategies certainly help reduce the carbon footprint.

At C6 Energy, we utilise a well-researched and innovative technology to reduce carbon footprint and give back to our environment with Graphene enabled cell technology. 

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Sustainable batteries for a climate neutral economy

Batteries that maintain sustainability throughout the lifecycle are key to contributing to zero pollution in the environment. These batteries help promote sustainability in a competitive way and are also necessary for clean energy, green transport and ultimately achieving climate neutrality. Batteries that are sustainable, safe throughout the battery life and high-performing are the ones that produce the least possible environmental impact, using materials that are with respect to human rights and meet the ecological and social standards. Batteries must be safe, long-lasting and by the end of their life must be recycled, remanufactured, repurposed, ultimately feeding material that is valuable to the economy.

Promoting competitive sustainability

The requirements for batteries to be used in electric vehicles, automotive and industrial purposes indicate the responsible use of the sourced material with the restricted usage of substances that are potentially hazardous and instead use recycled materials with a lower carbon footprint, higher performance and durability. While at the same time successfully meeting the recycling targets that are vital to developing highly competitive and sustainable battery industries. Legal certainties help make large scale production of sustainable batteries possible and furthermore boost the capacity of sustainable battery production to appropriately and effectively respond to the ever-evolving market.

High-performance batteries for a sustainable environment

High-performance batteries will make a significant contribution to road transport electrification, which significantly contributes to reduced carbon emissions, increased use of E-vehicles over other forms of transport which ultimately facilitates a higher usage of renewable resources for energy production. Additionally, the aim must be to make efficient use of these resources for a minimalistic impact on the environment. In order to maintain the use of renewable resources along with the use of valuable material for batteries. For this, it is important to establish novel targets and requirements to develop sustainable batteries, followed by effective recycling and treatment of the batteries.

Conclusion

In order to improve the recycling process of the portable type of batteries, it is important to work towards a rise in the collection rate in the upcoming decades so that the batteries used at home and the material they are made with are not lost to the environment. The batteries then have to be effectively recycled and high recovery levels have to be achieved, especially for materials like lead, nickel, lithium, and cobalt. At C6 Energy, the batteries are high-performance, high-efficiency, and are sustainable with a green carbon footprint, contributing to a sustainable environment.

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Applications of a biomass gasifier for sustainable production of energy

The process of energy production utilizes several biomass-based processes, inclusive of direct combustion, gasification or fermentation. Amongst a number of technologies for energy production from biomass, the process of pyrolysis and gasification are considered to be the most promising ones. The production of natural gas or syngas indirectly or directly from biomass or organic mass can include both plant (waste derived from agriculture) and animal waste. The production of power or energy utilizing biomass in form of fuel involves the process of accessing a particular portion of biomass, referred to as the hydrocarbon part that can also be converted to heat energy. This type of energy generation can be considered to be renewable as sunlight can be used for the purpose of recycling the carbon present in the atmosphere through a process, collectively called as carbon fixation.

A majority of the present-day biofuel production is focused on liquid fuel production via fermentation for transportation purposes. However, electricity generation via biomass by way of empowering cell technology is proving to be more cost-effective and environment friendly. Since a shift towards electric vehicles is gaining popularity, the focus has shifted from liquid fuels to energy production from biomass. This option offers a great opportunity for the agriculture field to empower electric vehicles as part of the transportation energy, as many farms are presently making use of small-scale gasifiers for using waste from agriculture to produce energy.

Generating power from biomass

Energy can be generated from biomass in some important ways:

1. Pyrolysis: In this process, liquid fuels can be used to produce syngas.

2. Gasification: Gasification of biomass also leads to the production of syngas. Gasification of biomass on a small scale is being widely utilized for the conversion of agricultural waste to produce energy for the automobile industry.

The current biomass power production plants are based on directly combusting the available waste biomass, however, utilizing the process of fermentation for biogas production is also becoming increasingly common. Gasification of biomass is, on the other hand, a novel approach for the production of clean energy that needs further research and development. The interest in the concept of gasifiers for the production of energy, started approximately a century back and has continued to be researched to date.

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Understanding the difference between a carbon-neutral and a carbon-negative approach

The possibility of going beyond just being carbon neutral

With all the discussions happening about measuring the carbon footprints in the scientific world and moving towards becoming carbon neutral, a common question that arises is: Is it possible to go beyond just being carbon neutral and transform into being carbon negative? It is a reasonable question to ask as offsets are being utilised to reduce the quantity of carbon that an individual or a particular organisation emits. Also, is it really possible to reach a level where carbon-negative emissions are a reality? The answers to this could not be as direct and a straight cut to be a yes or a no. There are several ways in which carbon emissions can be reduced right from the source point. However, issues prevail when it comes to accurately defining what being carbon neutral and then further, carbon-negative is.

Aiming for carbon neutrality

Both carbon-negative and carbon-neutral are on one single plane and run parallelly, wherein one term utilises slightly higher offsets as compared to the other. In practice, an organisation or a person can be carbon neutral if they choose not to use anything from the carbon cycle, even for the shortest span of time. This is, however, impossible to achieve in reality as simply riding a bicycle also has a carbon footprint that is in association with the very initial phase of bike manufacture. This contributes to an individual’s personal carbon footprint. Similarly, a food item that is being shipped using a particular method that is partially carbon-free will surely have a carbon footprint that is associated with it. Fortunately, the carbon footprint of opting for transportation methods like riding a bicycle is minimal as compared to the other modes of transport and opting for more sustainable options makes it considerably easier to reduce the carbon footprint and then furthermore, aim for being carbon neutral.

Conclusion

Taking one step ahead towards offsetting greater than what an individual emits in terms of the carbon footprint is the actual difference between being carbon negative and carbon neutral. Therefore, in the present time, it is nearly impossible to be entirely carbon neutral. However, C6 Energy’s Graphene battery technology is envisioning the revolution of battery technology by being completely carbon-neutral, causing no harm to the environment and instead of contributing to a clean, green and sustainable environment.

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What is a carbon footprint and how is it calculated?

On a practical basis, measuring carbon footprint provides a number of direct benefits. By way of collecting data for a carbon footprint, it is easy to recognize and then prioritise where one can make the most significant improvements in terms of utilising fuel, energy and similar resources. 

 What is a carbon footprint? 

 In simple terms, it is a measure of the contribution made to climatic change. There are two main categories of carbon footprint including product and organisational carbon footprint. The former type of footprint is the greenhouse gas emissions that are emitted over a time span of twelve months and gives a figure, wherein the amount of carbon is expressed in terms of tonnes and more precisely a carbon dioxide equivalent. There are a total of six gases that are greenhouse gases and are emitted due to human activities that greatly contribute to the phenomenon of global warming. 

 Here is a step-wise guide that helps calculate the carbon footprint:

Deciding the scope-

 Initiate by setting boundaries for the footprint. The approach for the same will depend on an individual’s major sources of emissions i.e., the sources that decide the amount of data that is available. Carbon footprints include three scopes, wherein the third scope is the most complex to measure. For smaller businesses, measuring the emissions include vehicle usage and consumption of electricity. 

 Collection of data-

 Once the activities that have to be measured are well-identified, the collection of data can then begin utilising a metric that is relevant. These activities must be tracked accurately, jotted down and segregated into the three different scopes. 

 Calculate emissions-

 In order to precisely calculate the footprint, convert the collected data using the carbon dioxide equivalent factor of conversion for each of the emissions. It is a common practice to calculate the carbon footprint annually. It can furthermore be aligned with the period of accounting. 

 Effective usage for identification of improvement areas-

 Once the carbon footprint is calculated, the data can be used to identify the measures that can be taken to reduce carbon emissions in a cost-effective manner. For example, if the usage of electricity is making the greatest contribution to your carbon footprint, measures must be prioritized in a way that reduces the use of electricity. 

Offsetting the carbon footprint-

 From a business point of view, carbon footprint offsetting is a great opportunity to make improvements in terms of efficiency for business purposes and benefiting the bottom line. The progress can then be communicated both internally as well as externally for moving a step ahead towards a better environment. 

Conclusion

 At C6 Energy, the Graphene battery technology is an innovative green carbon footprint technology that significantly contributes to sustainable development for a cleaner and greener future.

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Carbon offsetting: A sustainable trend or not?

We all leave a carbon footprint behind as part of the modern-day world. Eating, travelling and even shopping, causes CO2 emissions to be released in the environment. In terms of an organization, all business activities, be it industrial processing, electricity generation or even simply commuting, contributes to the overall carbon footprint of the corporation. In order to effectively reach the targets of a stable climate, it is important to extensively cut down on the carbon emissions. However, even if we cut down on a maximum of the emissions, there would still be enough carbon that persists in the environment. This is why it becomes important to compensate for the same by providing support to projects that are aiming towards reducing the emissions. Carbon offsetting is about reducing the emissions and contributing positively to the environment.

What is carbon offsetting?

In theoretical terms, carbon offsetting is not complicated. It includes calculating the estimated emissions of the greenhouse gases that are potentially generated from mechanisms that involve any type of fossil-fuel burning and then offset the derived estimate through emission-reducing initiatives that are funded elsewhere. The carbon offset concept comes from the ‘Kyoto Protocol’, which was a nation-wide agreement attempting to stabilize the concentration of green-house gases present in the atmosphere. This was aimed at preventing any interference with the normal and stabilized climate of the earth.

On the carbon compliance market, countries exceeding their greenhouse gas emissions may purchase or trade carbon credits from countries with an emissions deficit. One credit equals one metric ton of greenhouse gas emissions. In the same way, businesses also can trade on the spin-off markets, offering carbon credits for using cleaner production methods to businesses with significant emissions… and the need for some green marketing.

Does carbon offsetting allow us to continue operating the way we are?

No. It does not.

Compensation is simpler and in fact cheaper than working towards reduced carbon emissions and figuring out ways to reduce it. However, in order to prevent the worst possible effects of climate change, we not only need to cut down on our emissions but additionally, offset greater than what we emit. Striving towards becoming carbon-neutral is one such approach.

We already exceeded the safe level of carbon dioxide in the atmosphere in 1987. Even if we cut emissions down to zero today, we would still need to remove that excess carbon from the atmosphere. We need to all become carbon negative. It is the same as with plastic. Yes, we need to stop letting more plastic get into the ocean, but we also need to invest in ways to clean up the waste that is already littering our oceans.

Conclusion

Even though we have already exceeded the level of carbon dioxide present in the atmosphere that is ‘safe’, cutting down on carbon emissions will still contribute to reducing excessive carbon that is present in the environment. C6 Energy is setting an example of carbon neutrality and contributing to the environment through reduced carbon emissions with its Graphene battery technology.

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Carbon neutral or Net-zero: What is the difference?

With an increase in the understanding of the climatic crisis, we are more aware of the harm that we are causing to ourselves, the environment and the economy of a country. It, therefore, becomes important to work towards reducing carbon and carbon emissions on an individualistic basis. Carbon neutral, zero emissions, net-zero, and carbon negative are all terms that are commonly heard. However, with an increased number of efforts that are being made towards a clean and sustainable environment, it is crucial to understand how these terms differ and what they actually mean. 

The actual difference between the two terms

Net-zero carbon and carbon neutral are two terms that are often used interchangeably. However, the two terms are not interchangeable. Carbon neutral refers to a policy that supports decreasing carbon emissions and ultimately achieving reduced carbon emissions with offsets. Net-zero carbon emissions, on the other hand, involve making certain changes that contribute to reducing the carbon emissions to the lowest possible amount and carbon offsetting is considered to be the very last resort. This is because carbon offsetting is used to counteract the vital emissions that remain post all the initiatives for carbon emission reduction have been made and implemented well. 


Be it carbon neutrality or net-zero carbon emissions, carbon offsetting functions to remove carbon dioxide from the environment. For carbon offsetting to actually count, the CO2 removal must be permanent and licenced or accredited. Projects that help achieve reduced emissions in the atmosphere offer both community and social benefits. These projects can include the planting of trees, conservation, afforestation, to funding projects that are empowering individuals to reduce their fossil fuel dependence. Additionally, investments can be made that reduce GHG emissions.

Initiatives that help achieve carbon neutrality

Offsetting projects as part of carbon neutrality improve and enhance rainwater absorption, production of food, improve the quality of soil and biodiversity. Projects that particularly enhance the quality of soil are pertinent to climate change, and global warming as the soil is the most significant store of carbon, holding three times the carbon that is present in the atmosphere. Soil quality is an important factor when it comes to carbon offsetting and is often overlooked. A net-zero carbon commitment focuses only on reducing carbon emissions. This approach requires an initial measurement of the carbon footprint. This can then be followed by strategic initiatives for reducing greenhouse gas emissions with effective implementation of solutions for renewable energy use and then, finally, carbon offsetting.

Conclusion

In order to protect the environment from global warming, net-zero carbon emissions must be achieved on a global level. It must also be persistent, meaning that the greenhouse gases that are removed from the atmosphere are not released back into the atmosphere. At C6 Energy, we develop Graphene battery technology that utilises green carbon for a green footprint.

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Significance of carbon negative solutions for reducing CO2 emissions

Achieving the desirable climate requires more than simply cutting down on the carbon emissions. In addition to this, it is almost impossible for all sectors and industries that come within these sectors to achieve absolutely zero carbon emissions in the coming decades. This is because it is extremely challenging to reduce carbon emissions in the agriculture sector and vehicle usage or mobility to zero. Additionally, it is a challenge to offset the greenhouse gases like nitrous oxide and methane. Taking important steps like keeping the global temperature steady and not allowing for a rise that exceeds 1.5 degrees greater than the pre-industrial level. These measures could contribute to considerably removing the CO2 from the atmosphere. It has been increasingly suggested that the global level transition of energy storage and consumption requires an entire portfolio of steps and technologies that contributes to the reduction in CO2 emissions.

Solutions that aim at reducing or cutting down on the carbon emissions can be categorised into three main groups: carbon-sink solutions that are nature-based, further enhancement of the existing natural processes and novel technologies. Within these categories, the individualistic approaches are interlinked in a number of ways that come with benefits that go beyond just the reduction in CO2 emissions. One of the easiest ways to develop carbon sinks is by stopping the cutting down of trees (deforestation) and opting for reforestation. In simple terms, trees are responsible for absorbing and storing carbon but once cut down, the dead trees increase the CO2 emissions. However, there are concerns about the forest wildfires potentially destroying the carbon store, so encouraging reforestation alone can not be considered a silver bullet.

Enhancement of the natural processes

The earth’s natural processes store carbon, however, the enhancement of the natural processes through effective, proactive and strategic management can help reduce the carbon emissions. For example, improvised land management techniques can effectively store CO2. These methods include the usage of seaweed and biochar. Waste management is important but is challenging. The organic waste can be converted into biochar and utilised as soil that minimizes the waste production, while at the same time, establishing a carbon sink. Seaweed plays a significant role in naturally moving C02 from the atmosphere into the oceanic sediments. With better management of the areas that are seaweed-dense are considered to be carbon negative and can facilitate reduced carbon emissions, ultimately leading to a better management of the environment whilst dealing with the climate crisis.

Conclusion

Innovative technologies that function to reduce the carbon emissions by targeting the source of CO2 and by facilitating the effective storage and consumption of carbon. C6 Energy’s Graphene battery technology facilitates the effective storage and consumption of energy that contributes to reduced carbon emissions by being completely carbon-neutral.

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