technology environment essay

Essay on Impact Of Technology On Environment

Students are often asked to write an essay on Impact Of Technology On Environment in their schools and colleges. And if you’re also looking for the same, we have created 100-word, 250-word, and 500-word essays on the topic.

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100 Words Essay on Impact Of Technology On Environment

Positive effects of technology.

Technology has made life easier and more comfortable. For example, solar panels use the sun’s energy to make electricity. This clean energy reduces pollution from coal plants. Also, electric cars don’t use gasoline, so they don’t release harmful gases into the air.

Negative Effects on Nature

On the other side, technology can harm our planet. Factories making phones and computers produce waste and chemicals that can hurt land and water. Cars and machines using oil release gases that warm our Earth, changing our climate.

Technology in Farming

In farming, technology like tractors and machines helps grow more food. But, using too many chemicals to protect plants can harm the soil and water. We must find a balance to protect our Earth.

Recycling and Saving Resources

Technology helps us recycle things like paper, plastic, and metal. This means we use less from nature. Also, technology like LED lights uses less electricity, which saves energy and helps our planet.

Technology can both help and hurt our environment. It’s important to use technology in a way that keeps our Earth safe and clean for everyone.

250 Words Essay on Impact Of Technology On Environment

Technology and nature.

Technology has changed the way we live. It has given us many good things like computers, smartphones, and medical machines. But it also affects the world around us. When we use technology, it can hurt the air, water, and land.

Using Resources

To make technology, we need to use a lot of materials from the Earth. This includes metals and oil. Taking these out of the ground can harm the land. It can also make the animals that live there lose their homes.

Waste and Pollution

After we use technology, it often becomes waste. Old phones and computers can harm the environment if they are not thrown away the right way. They have chemicals inside that can get into the ground and water. Factories that make technology also put smoke and other bad things into the air. This can make the air dirty and cause illnesses.

Technology needs energy to work. Most of the time, this energy comes from burning coal or gas. This adds to climate change because it puts gases into the air that make the Earth warmer.

Helping the Environment

But it’s not all bad. We also have technology that helps the environment. Solar panels and wind turbines make clean energy. Electric cars don’t pollute as much as cars that use gas. And we have machines that can recycle waste.

In the end, technology can be both good and bad for the environment. We need to think about how we use it and try to find ways to make it less harmful. This way, we can enjoy the benefits of technology without hurting the world around us.

500 Words Essay on Impact Of Technology On Environment

Technology has changed our world in many ways. It has made life easier and more fun. But it also affects the environment, which includes all the natural things around us like air, water, plants, and animals. We use technology to make things, move around, and even to talk to each other from far away. All of this can harm nature if we are not careful.

Factories and Air Pollution

Factories make lots of things we use every day. They make our clothes, toys, and even the phone or computer you might be reading this on. But when factories work, they often make smoke that goes into the air. This smoke can make the air dirty, which is called air pollution. Dirty air is not good for people to breathe, and it can also make it harder for plants and animals to live.

Cars, Buses, and the Air

Cars, buses, and trucks help us get from one place to another quickly. But they also add to air pollution. They burn fuel, like petrol or diesel, and this creates smoke that goes into the air. Too much smoke from vehicles can make the air unhealthy and lead to problems like more asthma attacks in people.

Throwing Things Away

We use a lot of things once and then throw them away. Things like plastic bags, bottles, and wrappers can end up in places they should not be, like the ocean or on the ground. This is bad for the environment because animals can get hurt by this trash, and it can also make the places we live look dirty.

Using Energy

We need energy to do almost everything, like turning on lights, playing video games, or keeping our food cold in the fridge. Most of the energy we use comes from burning coal, oil, or gas. When we burn these things, it can make the air dirty, just like cars and factories do.

Even though technology can harm the environment, it can also help it. We have made new kinds of energy that are cleaner, like solar or wind power. These do not make the air dirty. We also have electric cars that do not need petrol or diesel and do not add smoke to the air.

Recycling and Reusing

Recycling means taking something old and making it into something new. Instead of throwing things away, we can recycle paper, plastic, and metal. This means less trash in the environment and fewer new materials that we need to take from nature. Reusing things is also good. If we use things more than once, like a water bottle, we make less trash.

Technology has both good and bad effects on our environment. It has made some things harder for nature, like making the air dirty and creating trash. But we can use technology to find new ways to help, like making clean energy and recycling. If we are smart about how we use technology, we can take care of the environment and still enjoy all the good things that technology brings to our lives.

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• The impact of technology on the ...

The impact of technology on the environment and how environmental technology could save our planet

Courtesy of Edinburgh Sensors Ltd - TECHCOMP Group

This article takes a look at the paradoxical ideology that while the impact of technology on the environment has been highly negative, the concept of environmental technology could save our planet from the harm that has been done.  This idea is supported by WWF  1 , who have stated that although technology is a solution enabler it is also part of the problem.

The term ‘technology’ refers to the application of scientific knowledge for practical purposes and the machinery and devices developed as a result. We are currently living in a period of rapid change, where technological developments are revolutionising the way we live, at the same time as leading us further into the depths of catastrophe in the form of climate change and resource scarcity.

This article will begin by discussing the negative impact of technology on the environment due to the causation of some of the world’s most severe environmental concerns, followed by the potential that it has to save the planet from those same problems. Finally it will explore the particular environmental technology of the gas sensor and discuss how it plays a part in the mitigation of negative environmental consequences.

The Impact of Technology on the Environment

The industrial revolution has brought about new technologies with immense power. This was the transition to new manufacturing processes in Europe and the United States, in the period from about 1760 to 1840. This has been succeeded by continued industrialisation and further technological advancements in developed countries around the world, and  the impact of this technology on the environment has included the misuse and damage of our natural earth.

These technologies have damaged our world in two main ways; pollution and the depletion of natural resources.

1. Air and water pollution

Air pollution occurs when harmful or excessive quantities of gases such as carbon dioxide, carbon monoxide, sulfur dioxide, nitric oxide and methane are introduced into the earth’s atmosphere. The main sources all relate to technologies which emerged following the industrial revolution such as the burning of fossil fuels, factories, power stations, mass agriculture and vehicles. The consequences of air pollution include negative health impacts for humans and animals and global warming, whereby the increased amount of greenhouse gases in the air trap thermal energy in the Earth’s atmosphere and cause the global temperature to rise.

Water pollution on the other hand is the contamination of water bodies such as lakes, rivers, oceans, and groundwater, usually due to human activities. Some of the most common water pollutants are domestic waste, industrial effluents and insecticides and pesticides. A specific example is the release of inadequately treated wastewater into natural water bodies, which can lead to degradation of aquatic ecosystems. Other detrimental effects include diseases such as typhoid and cholera, eutrophication and the destruction of ecosystems which negatively affects the food chain.

2. Depletion of natural resources

Resource depletion is another negative impact of technology on the environment. It refers to the consumption of a resource faster than it can be replenished. Natural resources consist of those that are in existence without humans having created them and they can be either renewable or non-renewable. There are several types of resource depletion, with the most severe being aquifer depletion, deforestation, mining for fossil fuels and minerals, contamination of resources, soil erosion and overconsumption of resources. These mainly occur as a result of agriculture, mining, water usage and consumption of fossil fuels, all of which have been enabled by advancements in technology.

Due to the increasing global population, levels of natural resource degradation are also increasing. This has resulted in the estimation of the world’s eco-footprint to be one and a half times the ability of the earth to sustainably provide each individual with enough resources that meet their consumption levels. Since the industrial revolution, large-scale mineral and oil exploration has been increasing, causing more and more natural oil and mineral depletion. Combined with advancements in technology, development and research, the exploitation of minerals has become easier and humans are therefore digging deeper to access more which has led to many resources entering into a production decline.

Moreover, the consequence of deforestation has never been more severe, with the World Bank reporting that the net loss of global forest between 1990 and 2015 was 1.3 million km 2 . This is primarily for agricultural reasons but also logging for fuel and making space for residential areas, encouraged by increasing population pressure. Not only does this result in a loss of trees which are important as they remove carbon dioxide from the atmosphere, but thousands of plants and animals lose their natural habitats and have become extinct.

Environmental Technology

Despite the negative impact of technology on environment, a recent rise in global concern for climate change has led to the development of new environmental technology aiming to help solve some of the biggest environmental concerns that we face as a society   through a shift towards a more sustainable, low-carbon economy. Environmental technology is also known as ‘green’ or ‘clean’ technology and refers to the development of new technologies which aim to conserve, monitor or reduce the negative impact of technology on the environment and the consumption of resources.

The Paris agreement, signed in 2016, has obliged almost every country in the world to undertake ambitious efforts to combat climate change by keeping the rise in the global average temperature at less than 2°C above pre-industrial levels.

This section will focus on the positive impact of technology on the environment as a result of the development of environmental technology such as renewable energy, ‘smart technology’, electric vehicles and carbon dioxide removal.

• Renewable energy

Renewable energy, also known as ‘clean energy’, is energy that is collected from renewable resources which are naturally replenished such as sunlight, wind, rain, tides, waves, and geothermal heat. Modern environmental technology has enabled us to capture this naturally occurring energy and convert it into electricity or useful heat through devices such as solar panels, wind and water turbines, which reflects a highly positive impact of technology on the environment.

Having overtaken coal in 2015 to become our second largest generator of electricity, renewable sources currently produce more than 20% of the UK’s electricity, and EU targets means that this is likely to increase to 30% by 2020. While many renewable energy projects are large-scale, renewable technologies are also suited to remote areas and developing countries, where energy is often crucial in human development.

The cost of renewable energy technologies such as solar panels and wind turbines are falling and government investment is on the rise. This has contributed towards the amount of rooftop solar installations in Australia growing from approximately 4,600 households to over 1.6 million between 2007 and 2017.

• Smart technology

Smart home technology uses devices such as linking sensors and other appliances connected to the Internet of Things (IoT) that can be remotely monitored and programmed in order to be as energy efficient as possible and to respond to the needs of the users.

The Internet of Things (IoT) is a network of internet-connected objects able to collect and exchange data using embedded sensor technologies. This data allows devices in the network to autonomously ‘make decisions’ based on real-time information. For example, intelligent lighting systems only illuminate areas that require it and a smart thermostat keeps homes at certain temperatures during certain times of day, therefore reducing wastage.

This environmental technology has been enabled by increased connectivity to the internet as a result of the increase in availability of WiFi, Bluetooth and smart sensors in buildings and cities. Experts are predicting that cities of the future will be places where every car, phone, air conditioner, light and more are interconnected, bringing about the concept of energy efficient ‘smart cities’.

The technology of the internet further demonstrates a positive impact of technology on the environment due to the fact that social media can raise awareness of global issue and worldwide virtual laboratories can be created. Experts from different fields can remotely share their research, experience and ideas in order to come up with improved solutions. In addition, travel is reduced as meetings/communication between friends and families can be done virtually, which reduces pollution from transport emissions.

• Electric vehicles

The environmental technology of the electric vehicle is propelled by one or more electric motors, using energy stored in rechargeable batteries. Since 2008, there has been an increase in the manufacturing of electric vehicles due to the desire to reduce environmental concerns such as air pollution and greenhouse gases in the atmosphere.

Electric vehicles demonstrate a positive impact of technology on the environment because they do not produce carbon emissions, which contribute towards the ‘greenhouse effect’ and leads to global warming. Furthermore, they do not contribute to air pollution, meaning they are cleaner and less harmful to human health, animals, plants, and water.

There have recently been several environmental technology government incentives encouraging plug-in vehicles, tax credits and subsidies to promote the introduction and adoption of electric vehicles. Electric vehicles could potentially be the way forward for a greener society because companies such as Bloomberg have predicted that they could become cheaper than petrol cars by 2024 and according to Nissan, there are now in fact more electric vehicle charging stations in the UK than fuel stations 3 .

• ‘Direct Air Capture’ (DAC) – Environmental Technology removing Carbon from the atmosphere

For a slightly more ambitious technology to conclude with, the idea of pulling carbon dioxide directly out of the atmosphere has been circulating climate change mitigation research for years, however it has only recently been implemented and is still in the early stages of development.

The environmental technology is known as ‘Direct Air Capture’ (DAC) and is the process of capturing carbon dioxide directly from the ambient air and generating a concentrated stream of CO2 for sequestration or utilisation. The air is then pushed through a filter by many large fans, where CO2 is removed. It is thought that this technology can be used to manage emissions from distributed sources, such as exhaust fumes from cars. Full-scale DAC operations are able to absorb the equivalent amount of carbon to the annual emissions of 250,000 average cars.

Many argue that DAC is essential for climate change mitigation and that it can help reach the Paris Climate Agreement goals, as carbon dioxide in the air has been the main cause of the problem after all. However, the high cost of DAC currently means that it is not an option on a large scale and some believe that reliance on this technology would pose a risk as it may reduce emission reduction as people may be under the pretense that all of their emissions will simply be removed.

Although we cannot reverse the negative impact of technology on the environment caused by industrialisation, many believe that new environmental technology, such as renewable energy combined with smart logistics and electric transport, has the potential to bring about the rapid decarbonisation of our economy and the mitigation of further detrimental harm.

How can the environmental technology of Edinburgh Sensors’ Gas Sensor contribute?

Sensors play a huge part in the positive impact of technology on the environment as they often play a vital role in the monitoring and reduction of harmful activities. At Edinburgh Sensors, we produce bespoke gas sensing technology which can be used across a wide range of applications, many of which can be used to mitigate environmental concerns. This article presents just three of these applications; the monitoring of greenhouse gas emissions, the monitoring of methane using an infrared sensor and the detection of gases using a UAV drone.

1. Monitoring of Greenhouse Gas emissions:   https://edinburghsensors.com/news-and-events/measuring-greenhouse-gas-emissions/

Edinburgh Sensors Gascard NG provides high quality, accurate and reliable measurements of CO, CO2 and CH4. To find out how we can assist you with the measurement of greenhouse gas emissions, simply contact us.

2. Using an Infrared Sensor for reliable Methane monitoring:   https://edinburghsensors.com/news-and-events/infrared-sensor-gas-monitoring/

Edinburgh Sensors’ Gascard NG is used for methane detection in a range of research, industrial, and environmental applications including pollution monitoring, agricultural research, chemical processes and many more.

3. Using a UAV drone attached to a gas sensor to measure harmful gases:   https://edinburghsensors.com/news-and-events/uav-drone-methane-monitoring/

From monitoring global warming to tracking the spread of pollution, there are many reasons to use a drone in order to monitor carbon dioxide, methane and other hydrocarbon gas concentrations in remote or dangerous locations.

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How Can Technology Help Combat Climate Change

Setting targets is only the first step. How can countries and companies make sure they hit them? Image:  Pixabay

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Listen to the article

• After setting climate targets, countries and companies will need to quantify, reduce and monitor their emissions.
• This process can be complex, time-consuming and prone to errors, especially for novices.
• The right technology can simplify this process and make it more efficient, transparent and effective.
• Here are three ways climate change technology solutions – particularly AIoT.

As society pressures leaders for a more environmentally-friendly agenda, governments responsible for 63% of world emissions have committed to net zero with corporate net-zero commitments covering 12% of the global economy (representing $9.81 trillion in revenue).

However, it is not uncommon to see large disconnects between targets and actual emissions – when the talk and the walk must go hand-in-hand in terms of effective emission-reduction progress. In June 2021, when the G7 decided to make climate risk disclosure mandatory, seven of the most influential global economies indicated that carbon reporting and disclosures would play a vital role in ensuring that emission reduction targets are in fact met.

Setting a target is just the first step; the second is to understand and quantify the real emission baseline into measurable units. Next, a clear definition of the emissions reduction strategy must be built. Finally, near real-time monitoring of targets vs actual progress should be in place. Ultimately, if countries and companies are to achieve net zero, they need to monitor, reduce and, in some cases, offset the emissions they generate.

The journey can be complex for beginners; it can be time-consuming, very manual, and prone to errors. That should not prevent companies from joining the decarbonization wave. After all, beyond satisfying consumers and political leaderships, committing to net zero might also prove economical, as access to capital will prove increasingly difficult for those not embracing the energy transition. As 'carbon tax' or 'cap-and-trade' schemes become the most likely path forward, and as and access to capital is reduced for those who fail to embrace the energy transition, early net-zero movers will have a competitive financial edge over laggards.

Carbon-management process

Carbon management can be broken down into three main categories: emission measuring and reporting, abatement, and offsetting.

1. Measuring and reporting carbon footprint

The first step is to measure carbon emissions. The carbon reporting process involves the collection of CO2 data, organising by emission type and geographical segment. The data is then measured against internationally recognised carbon-accounting standards such as GHG protocol or ISO 14064-1 . Currently, emission data may be obtained through meter readings, purchase records, utility bills, engineering models, direct monitoring, mass balance, stoichiometry (the calculation of reactants and products in chemical reactions), or other methods for acquiring data from specific activities in the company’s value chain. Challenges associated with measuring and reporting commonly include the laborious data collection process, difficulty reviewing carbon footprints across business units and assets, as well as validating underlying assumptions of emissions.

2. Abatement planning and management

Abatement planning involves identifying key sources of emissions and implementing measures to reduce them. By categorising emissions in step one, businesses can then pinpoint and measure which processes emit the highest volumes of CO2 and optimise their carbon-abatement plan. To achieve this, abatement roadmaps set out targets and KPIs to reduce emissions, focusing on changing emission-heavy processes and implementing new technologies to reduce emissions. Due to the multiple variables that need to be considered in such planning, the process can be uncertain and complex. Furthermore, tracking the performance and progress of abatement programmes is laborious. Organizational challenges include a lack of both transparency regarding marginal cost-benefit of abatement programmes, and resources for managing and executing this abatement journey.

3. Carbon offsetting

Carbon offsetting is considered the option of last resort once all abatement efforts and decarbonization investments have been exhausted. It is a way of taking responsibility for unavoidable carbon emissions by paying for others to reduce or absorb CO2. Multiple types of projects are used for carbon offsets, ranging from environmental projects such as reforestation, to carbon-capture technologies and renewable energy production. Carbon credits are measurable, verifiable emission reductions and have been used as a means for governments and companies to offset carbon emissions. Further methods include the use of RECs (renewable energy certificates) to offset energy consumed from non-renewable sources. However, offsets also come with challenges, from accurate measurement to transparency and verification to ease of trade.

How technology can fight climate change

Artificial intelligence of things (AIoT) solutions are integral to tackling some of the challenges associated with carbon management. There are three main areas of focus to make carbon management more efficient, transparent and effective.

1. AIoT – integration into measurement and reporting

With a myriad of databases and systems involved with different carbon-producing assets, the labour required to simply categorise and organise the data from multiple business units and assets is immense. AIoT integration enables seamless sourcing of real-time activity level data and asset inventory data from a variety of systems. This provides an organization with the capability to efficiently structure, collect and transform data into reports for accurate emissions-monitoring and measurement, reducing overall efforts around data collection and enhancing data quality and report resolution.

2. Abatement intelligence – predictive analytics to simulate emissions over time

Abatement planning is a challenge primarily due to the lack of accurate measures for determining the emissions derived from certain processes. AIoT technology tackles this challenge by creating insights from real-time data to better predict process emissions. By analysing and learning through data from multiple processes, AIoT can refine the performance evaluation of abatement measures and optimise emissions predictions. Beyond optimising abatement strategies, this technology also lowers the overall marginal abatement costs.

3. Carbon offsetting and offset integration

Although a last resort, the carbon offset market plays an essential role towards achieving global net-zero emissions goals for countries and organizations, with an estimated addressable market size of $200 billion by 2050 . However, verification of carbon offsetting and difficulty in trading plagues the industry. Technology can support validation of RECs in near real-time and offer a marketplace for affordable and fast carbon offsetting. Offset integration would provide a global pool of offsets to an organisation, improving ease of trade and emissions planning, reducing organizational hassle, and optimising the timings of REC purchases and retirement.

Carbon management solutions are essential to meeting the G7’s mandatory climate risk disclosures. More importantly, they provide the technology to actively manage and reduce carbon emissions and achieve the net-zero pledges made by governments and corporations. Driven by strong political, societal and economic agendas, carbon management solutions will be an integral part of emission reductions. For that, real-time measurement, abatement, and offset integration will help ensure companies not only talk the talk but also walk the walk and transparently meet their net-zero targets.

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