UFSCar Pioneers Sustainable Electrosynthesis of Amines from Air Nitrogen with FAPESP Funding

Revolutionary Breakthrough at UFSCar: Sustainable Electrosynthesis of Amines from Air Nitrogen

In a groundbreaking advancement for green chemistry, researchers at the Federal University of São Carlos (UFSCar) have developed a sustainable electrosynthesis method to produce valuable amines directly from atmospheric nitrogen. This innovation, supported by the São Paulo Research Foundation (FAPESP), promises to transform how Brazil's chemical industry approaches nitrogen fixation, bypassing energy-intensive traditional processes.

The study, published in ACS Electrochemistry, demonstrates the direct conversion of N₂ gas and acetone into propylamines like isopropylamine and diisopropylamine using an amorphous molybdenum disulfide (MoS₂) catalyst. Conducted under mild conditions—room temperature, atmospheric pressure, and aqueous solution—this process leverages renewable electricity, marking a significant step toward decarbonizing chemical manufacturing in Brazil's higher education ecosystem.

Led by Professor Lucia Helena Mascaro and postdoctoral researcher Caio Vinícius da Silva Almeida at UFSCar's Department of Chemistry, the work is part of the Center for the Development of Functional Materials (CDMF), a FAPESP-funded Center of Research, Innovation, and Dissemination (CEPID). This collaboration with the University of Bath in the UK highlights Brazil's growing prowess in electrochemical research.

UFSCar's contribution underscores the vital role of public universities in driving sustainable innovation. As Brazil grapples with industrial emissions and resource scarcity, such university-led projects offer actionable pathways for eco-friendly production, fostering expertise among students and faculty alike.

The Critical Role of Amines in Chemistry and Industry

Amines, organic compounds featuring a nitrogen atom bonded to carbon or hydrogen groups (R-NH₂, R₂NH, or R₃N), are foundational building blocks. They appear in pharmaceuticals (e.g., antidepressants), agrochemicals (pesticides), polymers, dyes, and cosmetics as stabilizers or active ingredients.

In Brazil, the chemical sector relies heavily on amines for manufacturing. Isopropylamine, for instance, is key in herbicides and surfactants, while diisopropylamine supports pharmaceutical synthesis. Traditional production stems from the Haber-Bosch process—fixing N₂ to ammonia (NH₃) at 400–500°C and 200 atm—followed by multi-step alkylation with fossil-derived feedstocks. This consumes 1–2% of global energy and emits ~1.5% of CO₂, posing sustainability challenges amid Brazil's net-zero ambitions.

UFSCar's method skips ammonia, directly coupling N₂ with acetone via electrochemistry, aligning with global shifts to electrified synthesis powered by renewables like Brazil's hydropower and solar boom.

Spotlight on the Research Team and CDMF at UFSCar

Professor Lucia Helena Mascaro, a leading electrochemist at UFSCar, coordinates research at CDMF. With expertise in nanomaterials and electrocatalysis, she has garnered international acclaim, including FAPESP fellowships and awards for women in chemistry. Postdoc Caio Vinícius da Silva Almeida, FAPESP scholar, spearheaded experiments, building on prior ammonia electrosynthesis work.

Co-authors Ana B. Cardile (UFSCar) and Frank Marken (Bath) contributed catalyst design and international validation. CDMF, hosted at UFSCar since 2013, exemplifies FAPESP's CEPID model: multi-institutional hubs training 100+ PhDs annually in functional materials for energy and environment.

This project trains graduate students in advanced electrochemistry, equipping Brazil's next generation for green tech roles. UFSCar's labs provide hands-on experience with flow cells and spectroelectrochemistry, vital for scaling innovations.

FAPESP's Pivotal Funding in Brazil's Research Landscape

FAPESP, São Paulo's flagship agency, invests R$1.2 billion yearly in research, funding 25% of Brazil's scientific output. CEPIDs like CDMF receive long-term support (15 years), enabling high-risk, high-reward projects like this electrosynthesis.

In higher education, FAPESP bridges academia-industry gaps via PIPE (small business innovation) and partnerships with multinationals. For UFSCar, it sustains 200+ projects, boosting h-index and patents. This amine research exemplifies how state funding propels federal universities toward UN SDGs, particularly Goal 9 (innovation) and 12 (sustainable production).

Brazil's public universities (e.g., USP, Unicamp, UFSCar) lead 70% of national R&D, with FAPESP amplifying impacts through international collaborations.

Step-by-Step: Mastering the Electrosynthesis Process

1. Catalyst Preparation: Amorphous MoS₂ deposited on carbon paper electrodes via drop-casting or electrodeposition. MoS₂'s edge sites activate N₂.
2. Electrolyte Setup: Aqueous solution with acetone (carbon source, 0.1–0.5 M) and phosphate buffer (pH 7).
3. N₂ Feed: Purified N₂ bubbled continuously.
4. Electroreduction: Apply -0.75 to -0.95 V vs SCE. N₂ reduces to reactive species coupling with acetone radicals.
5. Product Formation: Isopropylamine (single addition) and diisopropylamine (double) via reductive amination.
6. Analysis: GC-MS quantifies yields; NMR confirms structures.

Yields peak at moderate potentials; HER competes at higher reductions.

Impressive Results: Yields and Efficiencies Achieved

Experiments yielded 3.1 μg h⁻¹ mg⁻¹cat isopropylamine and 6.7 μg h⁻¹ mg⁻¹cat diisopropylamine at -0.85 V, with Faradaic efficiencies up to 2% for diisopropylamine. Acetone concentration boosts selectivity; N₂ saturation essential (Ar controls confirm).

Stable over 10 hours, no catalyst degradation. Compared to ammonia electrosynthesis (efficiencies <1%), this direct C-N bond formation excels for complex amines.

Why This Outshines Conventional Methods

• Energy Savings: Ambient vs. Haber-Bosch's extremes.
• Feedstock: Air N₂ + bio-acetone vs. fossils.
• Steps: One-pot vs. multi-stage.
• Scalability: Flow cells for industry; renewables integration.
• Brazil Fit: Leverages cheap hydro/solar power; reduces import reliance (Brazil imports 90% chemicals).

Globally, electrosynthesis market grows 15% CAGR; Brazil poised via UFSCar-like hubs.

Impacts on Brazil's Chemical Sector and Sustainability Goals

Brazil's R$200B chemical industry (5% GDP) emits 20Mt CO₂/year. This tech cuts emissions 80% for amines, aiding PNMC (Climate Plan). Amines demand: 50kt/year, growing 5% with biofuels/pharma.

UFSCar/CDMF patents could spawn startups via FAPESP PIPE, creating jobs in São Paulo's tech valley. Universities train 5k chemists/year; green skills demand surges.

Challenges Ahead and Optimization Pathways

Current yields low (2% FE); HER competes. Solutions: Dope MoS₂, nanostructure electrodes, membrane reactors. Scale-up tests needed; toxicity/purity for pharma.

Team eyes continuous flow, AI-optimized potentials. FAPESP renewals target 10x efficiency.

Brazil's Rising Star in Electrochemical Research

UFSCar joins USP/Unicamp in electrochemistry. FAPESP funds 50+ projects; Brazil publishes 10% Latin American electrochem papers. Global ties (Bath) boost impact factors.

Public universities host 80% green chem labs; attract EU/UK grants amid energy transition.

Career Horizons in Green Chemistry at Brazilian Universities

This breakthrough spotlights faculty/postdoc roles in electrocatalysis. UFSCar hires for CDMF; demand for PhDs in materials chem up 20%. Explore research jobs or faculty positions in sustainable tech.

Skills: Electrochemistry, catalysis, sustainability—gold for industry/academia.

Future Outlook: Scaling Innovation for a Greener Brazil

UFSCar's amine electrosynthesis heralds electrified chemistry era. With FAPESP backing, Brazilian universities lead sustainable nitrogen use, slashing emissions and fostering self-reliance. As industry adopts, expect prototypes by 2030, training thousands in cutting-edge research.

Photo by Karl Solano on Unsplash