28 Analytical Instrumentation TALKING POINT Why green ammonia is unlikely to be the fuel of the future –
but might just be its side-kick The quest for a zero-carbon future has ignited interest in various energy carriers and fuels that can potentially replace fossil fuels. Among the candidates, hydrogen stands out as a front-runner due to its high energy content and zero-emission profi le upon combustion or use in fuel cells. Ammonia (NH3
),
often touted for its ease of storage and transport, might seem like another promising option. However, its prospects as a fuel are dimmed by signifi cant drawbacks, making it more suitable as a hydrogen storage medium rather than a fuel for the future.
The argument against ammonia as a direct fuel is twofold: compatibility with fuel cells and pollution from combustion.
Firstly, most fuel cells, designed to generate electricity through a chemical reaction, are optimised for pure hydrogen. While research is ongoing into direct ammonia fuel cells, these technologies are nascent and currently less effi cient compared to their hydrogen counterparts. The process of cracking ammonia back into hydrogen to feed standard fuel cells adds an extra layer of complexity and energy use, making it less direct and effi cient than using hydrogen alone.
Secondly, when ammonia is combusted, it releases nitrogen oxides (NOx
), which are potent pollutants contributing to
smog and acid rain, and have signifi cant health impacts. Controlling these emissions requires additional technologies that increase the complexity and cost of using ammonia as a fuel. This environmental burden undermines the very goal of transitioning to cleaner energy systems.
Despite these challenges, ammonia has not been sidelined in the renewable energy conversation. It has a promising role as a storage medium for hydrogen. Ammonia’s chemical stability allows it to be liquifi ed more easily than hydrogen— at atmospheric pressure, it liquifi es at -33°C, compared to
hydrogen which requires a chilling -253°C. This property signifi cantly simplifi es the logistics of storage and transport.
How, then, can ammonia be transformed back into hydrogen? The process is known as ammonia cracking, and it involves catalytic or thermal methods to break the chemical bonds between nitrogen and hydrogen atoms in the ammonia molecule. The result is the release of hydrogen gas and nitrogen. With advances in catalytic technologies, this process is becoming more effi cient, positioning ammonia as a potential ‘hydrogen carrier’ that could enable the global distribution of hydrogen energy.
Turning to hydrogen, its role in a zero-carbon future is anchored in two critical applications: as a combustible material for industrial processes and as a means of generating electricity.
In industries that require high-temperature processes, such as steel or cement manufacturing, hydrogen can be combusted directly, producing water vapor as the only byproduct. This direct use bypasses the energy losses associated with converting hydrogen into electricity, then into heat, offering a cleaner alternative to fossil fuels without requiring extensive changes to existing infrastructure.
Furthermore, hydrogen is poised to play a vital role in energy systems through fuel cell technology. Fuel cells convert the chemical energy of hydrogen directly into electricity, with higher effi ciency than internal combustion engines and without the intermittent nature of solar or wind power. They offer a means to store energy in a form that is readily convertible to electricity, providing a solution for both base-load and peak power generation.
While batteries are also effi cient and essential for short-term energy storage and supply, hydrogen has the advantage for
long-duration storage and scalability. Batteries face challenges in raw material supply, costs, and life cycle environmental impacts, particularly for large-scale applications. In contrast, hydrogen can be produced wherever there is water and renewable electricity, such as solar or wind power, and stored indefi nitely in large quantities.
While ammonia’s environmental impact as a fuel makes it a less favorable candidate for direct energy applications, its utility as a hydrogen storage medium is undeniable. Ammonia enables the harnessing, storage, and transport of hydrogen’s clean energy across vast distances, from places where renewable energy is abundant to where it is needed.
Hydrogen’s role in the zero-carbon economy is multifaceted: as a clean combustible for industry and as a fl exible, effi cient energy carrier for electricity generation. Its integration into the global energy system is pivotal for achieving deep decarbonization and tackling the climate crisis head-on.
In the end, the energy transition is likely to see ammonia and hydrogen working in tandem, with each playing to its strengths to create a more sustainable and resilient energy future.
Solvent and waste level sensor
Introducing the GL Sciences SR-13 Solvent Level Sensor for chromatography - the cutting-edge solution for solvent level monitoring in your chromatography process.
Accurate solvent level monitoring is of critical importance in chromatography. Any deviations from the desired solvent level can compromise your analysis done, resulting in costly rework and lost productivity. That’s why the GL Sciences SR-13 Solvent Level Sensor was developed, a state-of-the-art solution that ensures precise and reliable solvent level measurements.
The GL Sciences SR-13 Solvent Level Sensor utilises advanced ultrasonic technology to provide high-precision measurements of liquid levels, regardless of the solvent. Even the diffi cult to monitor solvent Chloroform is no problem. Its non-invasive design eliminates the need for any contact with the solvent, preventing contamination and preserving solvent integrity. The solvent level changes are detected at high accuracy.
The sensor is easy to install and operate, with a simple interface that shows the actual status of your solvent level at a glance. The sensor stands alone and easily works in combination with any LC brand. Upon request an RS232 port can be installed for direct communication with your LC system to stop your LC instrument when the solvent level runs low. And with its compact and durable design, the GL Sciences SR-13 Solvent Level Sensor fi ts in any laboratory.
One GL Sciences SR-13 Main unit can connect to three separate sensors, either for your 1 litre solvent bottle or your waste container(s). By using two solvent sensors, your gradient method is safe from depleting unnoticed. The interface shows the measured level by displaying 1-4 LED lights. Once the solvent level drops below 25%, one orange LED will show. In case the solvent level drops below 10%, a red LED will start blinking and a continuous sound will be heard.
GL Sciences is committed to delivering the highest quality solutions to their customers. The GL Sciences SR-13 Solvent Level Sensor for Chromatography is no exception - it is a reliable and accurate tool that will help you optimise your chromatography process.
More information online:
ilmt.co/PL/z1L7 For More Info, email:
email: PIN ANNUAL BUYERS’ GUIDE 2024 For More Info, email:
59975pr@reply-direct.com
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