POTENTIALITY OF URANIUM ADSORPTION AND ITS ASSOCIATED ELEMENTS FROM WASTE LABORATORY LIQUIDS USING BLACK TEA WASTE

pH: The Sweet Spot

• Optimal Range: pH 4.5–5.5.
  • Below pH 4: Competing H⁺ ions reduce adsorption.
  • Above pH 5.5: Uranium hydrolyzes, forming precipitates .

Contact Time

• 60 minutes achieves ~95% uranium removal.
• Longer periods yield diminishing returns .

Initial Uranium Concentration

• Max Capacity: 60.56 mg U per gram of tea waste—one of the highest reported for bio-adsorbents .
• Efficiency drops at concentrations >2000 ppm due to saturation .

Solid-Liquid Ratio

• 1:50 (tea waste:solution) balances cost and efficiency, achieving 95.7% removal .

Table 1: Factors Affecting Uranium Adsorption

Factor	Optimal Condition	Efficiency Impact
pH	4.5–5.5	95% U removal
Contact Time	60 minutes	~95% adsorption
Initial U Concentration	≤100 ppm	4.79 mg/g uptake
Solid-Liquid Ratio	1:50	95.7% efficiency

Real-World Application: From Lab to Wastewater

Synthetic vs. Actual Waste

• Synthetic Solutions: Tea waste removed 60.56 mg/g U, plus 40–60% of Cd, Pb, and Th .
• Lab Waste Tests: 500 mL of real wastewater treated with 10g tea waste achieved >90% U and Th removal .

Table 2: Adsorption Performance for Key Elements

Element	Adsorption Capacity (mg/g)	Efficiency (%)
Uranium (U)	60.56	95.7
Thorium (Th)	18.2	89.3
Rare Earths	12–15*	65–70

*Varies by specific REE .

Elution and Recovery

• Elution: Acidified sodium chloride (0.5M H₂SO₄ + 1M NaCl) strips ~98% of adsorbed U and Th for reuse .
• Concentrate Production: Precipitated REE hydroxides and ammonium diuranate achieve >90% purity .

Table 3: Elution Efficiency

Eluent	U Recovery (%)	Th Recovery (%)
0.5M H₂SO₄ + 1M NaCl	98.2	97.5
1M HCl	92.4	88.1

Beyond Uranium: Tackling Multiple Contaminants

Black tea waste isn’t a one-trick pony:

• Heavy Metals: Removes 80–90% of Cu, Pb, and Cd .
• Organic Dyes: Adsorbs methylene blue (85% efficiency) via π-π interactions .

Why This Matters: Sustainability Meets Innovation

• Circular Economy: Transforms waste into a resource—1kg of tea waste can treat ~100L of contaminated water.
• Cost-Effective: ~$0.50/kg vs. $20–50/kg for activated carbon .
• Scalability: Simple preparation suits low-tech settings, ideal for developing nations.

Conclusion: A Steep Solution for a Cleaner Planet

Black tea waste exemplifies nature-inspired innovation. By harnessing its adsorption power, we can decontaminate hazardous lab liquids sustainably while reducing agricultural waste. Future research aims to enhance selectivity for REEs and integrate tea-based filters into industrial workflows. As nuclear energy grows, solutions like this will be vital for a safer, greener future.