Solar Urea: Towards a Sustainable Fertilizer Industry

Xia, Meikun; Mao, Chengliang; Gu, Alan; Tountas, Athanasios A.; Qiu, Chenyue; Wood, Thomas E.; Li, Young Feng; Ulmer, Ulrich; Xu, Yangfan; Viasus, Camilo J.; Ye, Jessica; Qian, Chenxi; Ozin, Geoffrey A.

doi:10.1002/anie.202110158

Cited by 44 publications

(24 citation statements)

References 27 publications

(12 reference statements)

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“…[7] Feng et al demonstrated Te-doped Pd nanocrystals promoted urea synthesis by coupling CO 2 RR with electrochemical reduction of nitrite. [8] Yuan et al found a novel Mott-Schottky Bi-BiVO 4 heterostructures-enabled urea synthesis from N 2 and CO 2 , with a Faradaic efficiency increased to 12.55%. [9] However, to the best of our knowledge, no reports currently exist utilizing solar energy for urea synthesis to reduce the intensity of its operating conditions.…”

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confidence: 99%

Solar Urea: Towards a Sustainable Fertilizer Industry

Xia

Mao

et al. 2021

Angewandte Chemie

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Urea, an agricultural fertilizer, nourishes humanity. The century-old Bosch-Meiser process provides the worlds urea. It is multi-step, consumes enormous amounts of nonrenewable energy, and has a large CO 2 footprint. Thus, developing an eco-friendly synthesis for urea is a priority. Herein we report a single-step Pd/LTA-3A catalyzed synthesis of urea from CO 2 and NH 3 under ambient conditions powered solely by solar energy. Pd nanoparticles serve the dual function of catalyzing the dissociation of NH 3 and providing the photothermal driving force for urea formation, while the absorption capacity of LTA-3A removes by-product H 2 O to shift the equilibrium towards urea production. The solar urea conversion rate from NH 3 and CO 2 is 87 mmol g À1 h À1 . This advance represents a first step towards the use of solar energy in urea production. It provides insights into green fertilizer production, and inspires the vision of sustainable, modular plants for distributed production of urea on farms.Humans and animals excrete excess nitrogen in the form of urea. Historically, urea was the first naturally occurring organic compound to be synthesized by Friedrich Wçhler in 1828. Surprisingly at the time, he made all-organic urea by a thermally induced reconstruction of an all-inorganic compound, ammonium cyanate, connecting the fields of organic and inorganic chemistry.

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Solar Urea: Towards a Sustainable Fertilizer Industry

Xia

Mao

et al. 2021

Angewandte Chemie

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“…In particular, tandem catalysis is preferable to approach challenging synthetic targets, which enables multicenter collaboration and coherent bond transformations. With these joint efforts, multielectron and proton photochemistry will offer more competitive solutions to store the abundant photons (i.e., solar energy) into valuable chemical bonds at ambient temperatures and pressures, such as photocatalytic “green hydrogen” production, ammonia synthesis, , urea synthesis, as well as CH 4 activation, in place of conventional industrial processes that cause severe fossil fuel consumption and CO 2 emission. In addition, multielectron and proton photochemical reactivities will enable versatile and promising opportunities to recycle “wasted” substances such as CO 2 into value-added compounds such as C1 fuels, carboxylic compounds, and multicarbon feedstocks, maintaining carbon-neutrality for chemical manufacturing (Figure c). ,− Along this line, we are getting unprecedently close to the visions by pioneering photochemists: versatile multielectron and multiproton photochemical synthesis will not only match and even outcompete the quantum efficiency, chemo-selectivity, regio-selectivity, stereoselectivity, and scalability of natural photosynthesis but also offer energy-economic, step-economic, carbon-neutral, and value-added solutions for sustainable chemical manufacturing in the next few decades.…”

Section: Discussionmentioning

confidence: 99%

Section: ■ Tandem Catalysis For Multielectron and Proton Transformationsmentioning

confidence: 99%

“…In this situation, tandem catalysis will be advantageous to collaborate light harvesting, charge transfer, proton transfer, and bond modification kinetics across broad time scales, thus facilitate consecutive multielectron and proton transformations. These efforts, along with advanced catalyst design, deeper mechanistic insights, and theoretical calculations, will boost more effective light utilization toward valuable photochemical synthetic opportunities, such as transforming abundant small molecules (e.g., H 2 O, CO 2 , N 2 ) to upgraded fuels (e.g., H 2 , CH 4 ), fertilizers (e.g., NH 3 , urea), and value-added chemicals at enhanced atom-economy, step-economy, regio-selectivity, and stereoselectivity.…”

Section: Introductionmentioning

confidence: 99%

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Photochemistry Journey to Multielectron and Multiproton Chemical Transformation

Meng

Wang

et al. 2022

J. Am. Chem. Soc.

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The odyssey of photochemistry is accompanied by the journey to manipulate “electrons” and “protons” in time, in space, and in energy. Over the past decades, single-electron (1e–) photochemical transformations have brought marvelous achievements. However, as each photon absorption typically generates only one exciton pair, it is exponentially challenging to accomplish multielectron and proton photochemical transformations. The multistep differences in thermodynamics and kinetics urgently require us to optimize light harvesting, expedite consecutive electron transfer, manipulate the interaction of catalysts with substrates, and coordinate proton transfer kinetics to furnish selective bond formations. Tandem catalysis enables orchestrating different photochemical events and catalytic transformations from subpicoseconds to seconds, which facilitates multielectron redox chemistries and brings consecutive, value-added reactivities. Joint efforts in molecular and material design, mechanistic understanding, and theoretical modeling will bring multielectron and proton synthetic opportunities for fuels, fertilizers, and chemicals with enhanced versatility, efficiency, selectivity, and scalability, thus taking better advantage of photons (i.e., sunlight) for our sustainable society.

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“…Few studies propose using direct solar or radiant energy for urea synthesis by photocatalysis. One of the latest publications in this field presents the simultaneous photocatalyzed reduction of NH 3 and CO 2 on palladium nanoparticles with promising results [40]. This review analyzes a hardly explored alternative route to industrial urea synthesis: photochemical production using TiO 2 -based materials.…”

Section: Industrial Synthesis Of Urea and Alternative Synthesesmentioning

confidence: 99%

Photocatalyzed Production of Urea as a Hydrogen–Storage Material by TiO2–Based Materials

2022

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This review analyzes the photocatalyzed urea syntheses by TiO2–based materials. The most outstanding works in synthesizing urea from the simultaneous photocatalyzed reduction of carbon dioxide and nitrogen compounds are reviewed and discussed. Urea has been widely used in the agricultural industry as a fertilizer. It represents more than 50% of the nitrogen fertilizer market, and its global demand has increased more than 100 times in the last decades. In energy terms, urea has been considered a hydrogen–storage (6.71 wt.%) and ammonia–storage (56.7 wt.%) compound, giving it fuel potential. Urea properties meet the requirements of the US Department of Energy for hydrogen–storage substances, meanly because urea crystalizes, allowing storage and safe transportation. Conventional industrial urea synthesis is energy–intensive (3.2–5.5 GJ ton−1) since it requires high pressures and temperatures, so developing a photocatalyzed synthesis at ambient temperature and pressure is an attractive alternative to conventional synthesis. Due to the lack of reports for directly catalyzed urea synthesis, this review is based on the most prominent works. We provide details of developed experimental set–ups, amounts of products reported, the advantages and difficulties of the synthesis, and the scope of the technological and energetic challenges faced by TiO2–based photocatalyst materials used for urea synthesis. The possibility of scaling photocatalysis technology was evaluated as well. We hope this review invites exploring and developing a technology based on clean and renewable energies for industrial urea production.

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Solar Urea: Towards a Sustainable Fertilizer Industry

Cited by 44 publications

References 27 publications

Solar Urea: Towards a Sustainable Fertilizer Industry

Solar Urea: Towards a Sustainable Fertilizer Industry

Photochemistry Journey to Multielectron and Multiproton Chemical Transformation

Photocatalyzed Production of Urea as a Hydrogen–Storage Material by TiO2–Based Materials

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