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Reduction of Alkenes: Catalytic Hydrogenation02:13

Reduction of Alkenes: Catalytic Hydrogenation

12.0K
Alkenes undergo reduction by the addition of molecular hydrogen to give alkanes. Because the process generally occurs in the presence of a transition-metal catalyst, the reaction is called catalytic hydrogenation.
Metals like palladium, platinum, and nickel are commonly used in their solid forms — fine powder on an inert surface. As these catalysts remain insoluble in the reaction mixture, they are referred to as heterogeneous catalysts.
The hydrogenation process takes place on the...
12.0K
Reduction of Benzene to Cyclohexane: Catalytic Hydrogenation01:28

Reduction of Benzene to Cyclohexane: Catalytic Hydrogenation

4.6K
Unlike the easy catalytic hydrogenation of an alkene double bond, hydrogenation of a benzene double bond under similar reaction conditions does not take place easily. For example, in the reduction of stilbene, the benzene ring remains unaffected while the alkene bond gets reduced. Hydrogenation of an alkene double bond is exothermic and a favorable process. In contrast, to hydrogenate the first unsaturated bond of benzene, an energy input is needed; that is, the process is endothermic. This is...
4.6K
Reduction of Alkynes to cis-Alkenes: Catalytic Hydrogenation02:24

Reduction of Alkynes to cis-Alkenes: Catalytic Hydrogenation

7.7K
Introduction
Like alkenes, alkynes can be reduced to alkanes in the presence of transition metal catalysts such as Pt, Pd, or Ni. The reaction involves two sequential syn additions of hydrogen via a cis-alkene intermediate.
7.7K
Reduction of Alkenes: Asymmetric Catalytic Hydrogenation02:17

Reduction of Alkenes: Asymmetric Catalytic Hydrogenation

3.3K
Catalytic hydrogenation of alkenes is a transition-metal catalyzed reduction of the double bond using molecular hydrogen to give alkanes. The mode of hydrogen addition follows syn stereochemistry.
The metal catalyst used can be either heterogeneous or homogeneous. When hydrogenation of an alkene generates a chiral center, a pair of enantiomeric products is expected to form. However, an enantiomeric excess of one of the products can be facilitated using an enantioselective reaction or an...
3.3K
Alcohols from Carbonyl Compounds: Reduction02:23

Alcohols from Carbonyl Compounds: Reduction

10.4K
Reduction is a simple strategy to convert a carbonyl group to a hydroxyl group. The three major pathways to reduce carbonyls to alcohols are catalytic hydrogenation, hydride reduction, and borane reduction.
Catalytic hydrogenation is similar to the reduction of an alkene or alkyne by adding H2 across the pi bond in the presence of transition metal catalysts like Raney Ni, Pd–C, Pt, or Ru. Aldehydes and ketones can be reduced by this method, often under mild to moderate heat (25–100°C) and...
10.4K
Hydrogen Bonds01:04

Hydrogen Bonds

8.5K
A hydrogen bond is formed when a weakly positive hydrogen atom already bonded to one electronegative atom (for example, the oxygen in the water molecule) is attracted to another electronegative atom from another polar molecule, such as water (H2O), hydrogen fluoride (HF), or ammonia (NH3). The huge electronegativity difference between the H atom (2.1) and the atom to which it is bonded (4.0 for an F atom, 3.5 for an O atom, or 3.0 for an N atom), combined with the very small size of an H atom...
8.5K

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Related Experiment Video

Updated: Jul 4, 2025

A Simple, Low-cost, and Robust System to Measure the Volume of Hydrogen Evolved by Chemical Reactions with Aqueous Solutions
06:32

A Simple, Low-cost, and Robust System to Measure the Volume of Hydrogen Evolved by Chemical Reactions with Aqueous Solutions

Published on: August 17, 2016

19.6K

Formal optimization techniques select hydrogen to decarbonize California.

Clinton Thai1, Jack Brouwer2

  • 1Advanced Power and Energy Program, University of California, Irvine, CA, 92697-3550, USA.

Scientific Reports
|January 29, 2024
PubMed
Summary
This summary is machine-generated.

Integrating renewable energy to meet significant hydrogen demand (8 MMT/year) is crucial for deep decarbonization. This study models the 2050 California electric grid, revealing hydrogen

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Hydrogen Production and Utilization in a Membrane Reactor
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A Simple, Low-cost, and Robust System to Measure the Volume of Hydrogen Evolved by Chemical Reactions with Aqueous Solutions
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Synthesis of Metal Nanoparticles Supported on Carbon Nanotube with Doped Co and N Atoms and its Catalytic Applications in Hydrogen Production

Published on: December 6, 2021

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Area of Science:

  • Energy Systems Analysis
  • Environmental Science
  • Chemical Engineering

Background:

  • System planning across economic sectors is essential for deep decarbonization.
  • Existing solutions need to incorporate renewable energy integration for broader emission reductions.

Purpose of the Study:

  • To model the 2050 California electric grid with a substantial hydrogen demand (up to 8 MMT/year).
  • To evaluate the impact of renewable capacity, including offshore wind, on hydrogen production and grid operations.
  • To analyze four distinct scenarios based on hydrogen technology adoption and renewable energy availability.

Main Methods:

  • An hourly economic dispatch model was developed for the 2050 California electric grid.
  • Simulations incorporated fixed hydrogen demand (non-power sector) and endogenously determined power generation demand.
  • Four scenarios were evaluated, varying offshore wind capacity and hydrogen technology adoption rates.

Main Results:

  • Achieved 27 MMT carbon reduction outside the power sector, despite a minor increase within it.
  • Seasonal hydrogen storage requirements ranged from 72 to 149 TBtu.
  • Hydrogen production utilized 21% to 41% of the total electric load.

Conclusions:

  • Hydrogen integration can significantly contribute to economy-wide decarbonization.
  • Substantial renewable capacity and grid flexibility are required to meet high hydrogen demand.
  • Optimal energy storage strategies are influenced by seasonal hydrogen demand and electrolyzer operation.