Question 1 - Hydrogen Generation

Question 1

Describe the concept of ‘Hydrogen Economy’

Answer 1

• Future energy system in which hydrogen plays a central role
• Shift from traditional energy sources
• Potential to significantly reduce greenhouse gases
• Hydrogen to be produced from renewable or low carbon sources such as electrolysis of water using renewable electricity, steam reforming with carbon capture and storage (CCS), biomass gasification, or other emerging technologies.

Question 2

Major issues associated with ‘Hydrogen Economy’

Answer 2

• Cost: mostly due to the energy intensive nature of current hydrogen production methods
• Infrastructure: Infrastructure for production, transportation, and distribution is under developed
• Energy efficiency: The production, storage, and utilization of hydrogen involve energy losses at each stage, reducing overall energy efficiency
• Scalability and Scale-up: Scaling up hydrogen production to meet the requirements of various sectors would require significant investment, research, and development
• Sustainability: Hydrogen produced from fossil fuel-based processes, such as steam methane reforming without carbon capture, can still result in greenhouse gas emissions.
• Safety: Hydrogen is highly flammable and has specific safety considerations.
• Public Acceptance: The general public’s awareness and acceptance of hydrogen as an alternative energy carrier may pose a challenge.

CRISES - Cost, Infrastructure, Energy efficiency, Scalability, Safety, Sustainability

Question 3

List the current methods used to produce hydrogen from biomass

Answer 3

Thermochemical vs Biological

Thermochemical:

• Gasification
• Pyrolysis
• High pressure aqueous

GPH

Biological:

• Anaerobic digestion
• Fermentation
• Metabolic processing

AFM

Question 4

Advantages of the ‘Hydrogen Economy’

Answer 4

Elimination of pollution caused by fossil fuel

Elimination of greenhouse gases

Elimination of economic dependence

Distributed and localized production

Question 5

Explain biomass gasification

Answer 5

Gasification is a thermochemical process that converts biomass into syngas. Which can be further processed to separate and purify hydrogen.

Undergoes pyrolysis

Oxygen-deficient environment must be created, favoring the production of syngas rather than complete oxidation / complete combustion

Question 6

What is syngas?

Answer 6

Syngas, short for synthesis gas, is a mixture of gases primarily composed of hydrogen (H2) and carbon monoxide (CO). It is produced through various processes, including biomass gasification, coal gasification, or steam reforming of natural gas. Syngas is a versatile fuel and feedstock that can be used in a range of applications.

Question 7

Explain pyrolysis

Answer 7

The thermal decomposition of the organic material in the absence of oxygen. This results in the release of volatile compounds, including gases and tars.

Question 8

The gasification reactions

Answer 8

In the presence of heat and limited oxygen, the volatile compounds released during pyrolysis react with steam (H2O) or carbon dioxide (CO2) to produce syngas. The main reactions involved are:

C + H2O → CO + H2
C + CO2 → 2CO
C + 2H2O → CO2 + 2H2

These reactions are endothermic, meaning they require heat energy to proceed.

Question 9

What are the 5 types of biomass?

Answer 9

W - Woody Biomass : Woody biomass refers to biomass derived from trees and woody plants.

A - Agricultural Biomass: Agricultural biomass comprises biomass residues and byproducts generated from agricultural activities.

G - Energy Crops: Specifically cultivated for their high biomass yield and energy content.

E - Algae: microscopic aquatic organisms that can convert sunlight, water, and carbon dioxide into biomass through photosynthesis.

O - Organic Waste: refers to biomass derived from organic materials that are discarded or considered waste. This includes food waste, agricultural waste, forestry residues, and municipal solid waste.

Question 10

Explain ‘anaerobic digestion’

Answer 10

Anaerobic digestion is a biological process that utilizes microorganisms to break down organic matter in the absence of oxygen, resulting in the production of biogas. Biogas is a mixture of gases, primarily composed of methane (CH4) and carbon dioxide (CO2), with smaller amounts of trace gases such as hydrogen (H2), nitrogen (N2), and hydrogen sulfide (H2S).

Question 11

Explain ‘fermentation’ for the production of H2 from biomass

Answer 11

Fermentation involves the use of microorganisms to convert organic matter into H2 gas. It is a natural metabolic process that occurs in the absence of oxygen (anaerobic conditions).

Question 12

Explain ‘Metabolic Processing’ for the production of H2 from biomass

Answer 12

The utilization of specific metabolic pathways and enzymes within microorganisms to produce H2 gas. Different metabolic pathways can be employed by microorganisms to convert organic matter into H2.

Question 13

Explain what ‘Biogas’ is

Answer 13

A renewable energy-rich gas produced by the breakdown of organic matter in the absence of oxygen, a process known as anaerobic digestion. It is primarily composed of methane (CH4) and carbon dioxide (CO2), with trace amounts of other gases such as nitrogen (N2), hydrogen sulfide (H2S), and small quantities of other volatile organic compounds.

Question 14

What are the 4 steps of producing hydrogen via steam reforming?

Answer 14

1. Feedstock pre-treatment : removes impurities which may deactivate the catalyst used
2. Catalytic steam reforming : feedstock is introduced into a reformer, which contains a catalyst, typically based on nickel (Ni). Steam reforming reaction takes place

CH4 + H2O -> CO + 3H2 (endothermic, requires high temp)

Heat required, generated by: CH4 + 2O2 -> CO2 + 2H2O

3. Water - Gas shift reaction : Used to turn the undesired CO into H2

CO + H2O -> CO2 + H2 (exothermic reaction, occurs at lower temp than previous reaction)

4. Gas clean-up : Purification steps are often taken at the end such as pressure swing adsorption or membrane separation to remove trace amounts of CO

F.I.R.E.H2O. O

Question 15

Biological hydrogen production:

Answer 15

• Dark fermentation : relies on anaerobic bacteria to break down organic matter in the absence of light. Through a series of biochemical reactions, these bacteria produce hydrogen as a byproduct.
• Photobiological Hydrogen Production: Certain photosynthetic microorganisms and algae have the ability to produce hydrogen through photosynthesis. Under specific conditions, they can divert their metabolic pathways to generate hydrogen gas instead of oxygen.

Question 16

Explain the Palladium membrane separation process

Answer 16

• operate via pressure driven diffusion across palladium membranes
• exhibit high permeability to hydrogen while selectively blocking the passage of other gases
• Palladium is very expensive
• H2 molecules in contact with the Pd membrane dissociate into monatomic hydrogen and pass through the membrane. When on the other side the monatomic hydrogen recombines back into molecular H2

Question 17

Describe the extraction of shale gas via ‘fracking’

Answer 17

Stage 1: Drill down to shale level

Stage 2: Water sand and chemicals pumped to a pressure of approx 1500 lb/inch^2, forcing the rock apart releasing the gas in the pores

Stage 3: Liquid pumped out of well, sand keeps the rock separated allowing gas to seep out of the broken shale layer to be piped to the surface.

Question 18

What is ‘Shale gas’ ?

Answer 18

Shale gas is methane (natural gas) which is trapped in impermeable shale rock deep underground

Question 19

What are the advantages and potential risks of ‘Fracking’ ?

Answer 19

Advantages:

• Increased energy production
• Economic benefits (i.e job creation)
• Reduced carbon emissions (produces lower co2 emissions than coal when combusted)
• Energy transition support

IREE

Risks and concerns:

• Water contamination
• Air pollution
• Seismic activity
• Habitat and wildlife disruption

WASH

Question 20

How can ‘Shale gas’ be utilized for producing hydrogen?

Answer 20

Steam methane reforming

Question 21

What are two current methods of purification of hydrogen?

Answer 21

• Pressure swing adsorption
• Pd membrane separation

Question 22

How does pressure swing adsorption work?

Answer 22

The process involves cyclic changes in pressure to selectively remove impurities from a gas stream.

Adsorption based on molecular weight at high P

Beds composed by zeolites, silica, and carbons

H2 = 99,99%

Question 23

What are some current methods of hydrogen storage?

Answer 23

• Compressed gas storage
• Liquid hydrogen storage (specialized storage facility)
• Metal Hydride
• Chemical Hydride

Question 24

What are some current methods of hydrogen transport?

Answer 24

• Compressed gas transport
• Liquid hydrogen transport
• Hydrogen pipelines

Question 25

Define biomass

Answer 25

Organic matter derived from living or recently living organisms, such as plants, animals, and microorganisms. It is a renewable energy resource that can be used to produce heat, electricity, and various bio-based products.

Question 26

What are the pros and cons of using biomass for hydrogen?

Answer 26

Pros:

• Renewable + Sustainable
• Carbon neutral
• Waste utilization
• Energy security

Cons:

• Land + resource requirements
• Logistics
• Energy density + efficiency
• Environmental impact (monocrops etc…)

Question 27

Explain what the ‘Hynol’ process is and state the chemical reactions that occur

Answer 27

Process which produces H2 and CH3OH from biomass.

Phase 1:

(1a) C + CH2 ==> CH4
(1b) C + 2H2O ==> CO + H2
(1c) CO2 + H2 ==> CO + H2O

Phase 2:

(2a) CH4 + H2O ==> CO2 + 3H2
(2b) CO2 + H2 ==> CO + H2O

Phase 3:

(3a) CO + 2H2 ==> CH3 + OH
(3b) CO2 + 3H2 ==> CH3OH + H2O

Question 28

Describe the bio diesel cycle (7 steps)

Answer 28

1. photosynthesis creates oil crops
2. oil crops create seeds
3. Crude vegetable oil extracted from seeds
4. Crude vegetable oil is refined to refined vegetable oil
5. alcohol is added for transesterification which produces bio-diesel and glycerol
6. Bio-diesel is used in the engine of a vehicle
7. Bio diesel is converted into energy and CO2

Question 29

Pros + cons of Bio-diesel

Answer 29

Pros:

• Renewable
• Reduced emissions
• Biodegradable
• Higher lubricity
• High flashpoint (safe)
• Can be used mixed in any ratio with petroleum diesel
• significant reduction in PM emissions (PM = particle matter)

Cons:

• Poor quality can cause problems in engines
• Availability and Production

Question 30

Describe the chemical reactions involved in the synthesis of bio diesel (4)

Answer 30

1. Transesterification : reaction involves the reaction of triglycerides (present in vegetable oils or animal fats) with an alcohol, in the presence of a catalyst.

Triglyceride + Alcohol → Biodiesel (Fatty Acid Methyl Esters) + Glycerol

2. Catalyst: Is used to facilitate the transesterification reaction. The most commonly used catalysts are strong bases, such as sodium hydroxide (NaOH) or potassium hydroxide (KOH).
3. Esterification: The esterification reaction involves the reaction of free fatty acids (FFA) present in the feedstock with the alcohol and catalyst.

Free Fatty Acid + Alcohol → Ester + Water

Important when the feedstock contains a significant amount of free fatty acids, as they need to be converted into esters to produce high-quality biodiesel.

4. Separation of Biodiesel and Glycerol:
   After the transesterification reaction, the mixture contains biodiesel (FAME), glycerol, unreacted alcohol, catalyst residues, and other impurities. The mixture is allowed to settle or undergo centrifugation to separate the biodiesel from the glycerol and other heavier components.

The separation process can involve multiple stages, such as washing, drying, and filtration, to remove impurities and improve the quality of the biodiesel.

Question 31

Carnol process: chemical reactions

Answer 31

This is a high T (two step process)

(i) Thermal conversion of CH4

CH4 —> C + 2H2

(ii) Methanol synthesis

CO2 + 3H2 —> CH3OH + H2O

(iii) Overall equation

2CO2 + 3CH4 —-> 2CH3OH + 2H2O + 3C

Question 32

How can the electrolysis of water be used for the production of hydrogen?

Answer 32

Electrolysis of water is a process that utilizes an electric current to split water molecules into hydrogen (H2) and oxygen (O2) gases

Electrolysis of water occurs in an electrolyzer, which consists of two electrodes (an anode and a cathode) immersed in a water-based electrolyte, typically a dilute solution of sulfuric acid or potassium hydroxide. When an electric current is applied, the following reactions take place:

At the anode (positive electrode):
2H2O → O2 + 4H+ + 4e-

At the cathode (negative electrode):
4H+ + 4e- → 2H2

Overall reaction:
2H2O → 2H2 + O2

The electrolysis process separates water into hydrogen gas at the cathode and oxygen gas at the anode.

Question 33

What is the potentiality and issues with electrolysis of water?

Answer 33

Issues:

• Energy Efficiency: Electrolysis of water requires a significant amount of electrical energy input.
• Cost
• Scalability presents logistical challenges

Potentiality:

• Renewable Energy Integration: Electrolysis can be powered by renewable energy sources such as solar, wind, or hydroelectric power.
• Energy Storage: Electrolysis provides a means to store excess renewable energy in the form of hydrogen
• Versatility: Hydrogen produced through electrolysis can be utilized in various sectors, including transportation, industry, and energy storage.

Question 34

Environmental impact of using fossil fuels/coal

Answer 34

• Greenhouse gas emissions
• Air pollution
• Water pollution
• Acid rain
• Land + habitat destruction

Question 35

How hydrogen can be generated from coal

Answer 35

1. Devolatilisation : From carbon to complex gaseous
   mixture and porous solid char residue
2. Gaseous mixture: Combination of partial oxidation, SR,
   and WGS reactions
3. Char particles: Gasified to CO through partial
   oxidation of C

C+ aO2 + bH2O —> cCO2 + dCO + eH2 + “other species”

Question 36

Coal Gasification reactions

• Partial oxidation of char
• Stream reforming (water gas reaction) of carbon
• WGS reaction

Answer 36

1. C + 1/2O2 <==> CO (exo)
2. C + H2O <===> CO + H2 (endo)

C + 2H2O <===> CO2 + 2H2 (endo)

3. CO + H2O <===> CO2 + H2 (exo)

Question 37

Coal gasification (CO cleanup) (2 types)

Answer 37

1. Chemical separation

• Selective methanation of CO ( + H2)
• Selective oxidation of CO (+ O2)

2. Physical separation

• Pressure swing adsorption
• Pd membrane separation