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My house is totally fucked
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2024-10-01 at 10:53 PM UTCThe following users say it would be alright if the author of this post didn't die in a fire!
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2024-10-01 at 11:04 PM UTCFona is that your deathbed? are you on your deathbed? OH GOD SAY IT ISNT SO I KNEW IT WAS COMING BUT THIS IS TOO SOON OH GOD WHY WHYYYY WHY GOD WHY"
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2024-10-02 at 12:30 AM UTC
Originally posted by 6835378gjjsjs That is less true with thr n-iso crap people assume is normal methamphetamine.
this is why everyone should learn to make their own organic solar meth from brewing ephedrine and or that one reduction with very easy to stockpile chemicals
Originally posted by the man who put it in my hood
Introduction
Since the U.S. Congress passed the Combat Methamphetamine Epidemic Act in March of 2006, the Drug Enforcement Administration (DEA) Methamphetamine Profiling Program (MPP) has seen a shift away from pseudoephedrine and ephedrine-based large-scale clandestine laboratory production of methamphetamine. This shift was observed from forensic analyses using an established analytical protocol [1], [2], [3], [4], [5], [6], [7], [8], [9], [10] of numerous high quality methamphetamine samples obtained from U.S.-Mexico border and domestic seizures. Since that time, the forensic results tell a chemical story that revolves around the chemical precursor known as phenyl-2-propanone (P2P), and since approximately 2009, the MPP has been tracking a methamphetamine clandestine P2P laboratory process that uses a foul-smelling crystalline material known as phenylacetic acid (PAA). This precursor is difficult to buy clandestinely; therefore, an ester of PAA, usually ethyl phenylacetate (EtPA), a perfume-like smelling oil sold in 200 L containers, is purchased. This oil is very easily transformed into PAA using acid and base chemistry for the eventual production of P2P (Fig. 1). The two main recipes to convert PAA with modest yields into P2P are the Dakin-West reaction that uses acetic anhydride and sodium acetate as essential chemicals and the lead acetate reaction [11], [12]. The former reaction is heated for several hours producing a dark brown solution, which is then later distilled to obtain the P2P product. The latter reaction proceeds via a destructive distillation process using PAA and lead acetate, which are easily handled solid materials. The resulting P2P oil produced from both of these reactions is converted to methamphetamine using either an amalgam or Leuckart reductive amination process. Impurities related to these processes have been well studied and are now routinely monitored in high purity methamphetamine samples [13], [14], [15]. The key impurities from these processes are known as the B-compound (α-benzyl-N-methylphenethylamine) and the P-compound (trans-N-methyl-4-methyl-5-phenyl-4-penten-2-amine) and are used to track the PAA-based methamphetamine results [16], [17].
It appears that the perfume oil (EtPA), and other related ester and amide materials became less available, because an alternative P2P recipe started to emerge onto the forensic scene in 2014. At that time, a new impurity pattern was identified in the gas chromatography-mass spectrometry (GC-MS) analyses results for a significant portion of the seized samples. This led to uncertainty for the MPP, with a spike in unknown synthetic route assignments, and a sharp decrease (84%) in samples assigned to a P2P-based recipe in the first quarter of 2015 (Fig. 2). This new and unknown profile was quickly solved and P2P-based assignments went back to status quo (above 90%) in recent reporting periods, from 2016 to 2018. It should be noted that another forensic profiling team located in Australia has also observed this new profiling pattern in seized methamphetamine samples [18].
The old clandestine method responsible for the newly observed profiling pattern is referred to by the MPP as the nitrostyrene (NTS) method (it could also be called the nitropropene method). It uses benzaldehyde and nitroethane as the two key precursor chemicals in the process (Fig. 3). A Knoevenagel reaction resulting in NTS has long been known to produce a translucent, yellow solid (possibly orange if not enhancemented and dried well) as an easily managed intermediate in the first step of the method [19]. This solid is then converted to P2P in a harsh reaction using iron powder and hydrochloric acid [19], which leaves behind black solid iron sludge as waste. The P2P oil is then converted to methamphetamine using the same reductive amination chemistry as mentioned earlier for PAA-based methamphetamine.
Herein, we report forensic evidence that supports the recent P2P recipe change to be from the nitrostyrene method and will show the impact of this method on methamphetamine samples seized in the U.S.A. from 2015 to 2018.Solvents, chemicals, and materials
All chemicals and solvents used were reagent grade or better. Petroleum ether and dichloromethane were obtained from VWR Corp. (West Chester, PA).
Reagents utilized for the nitrostyrene synthesis to P2P included nitroethane, benzaldehyde, iron powder, and iron (III) chloride (all from Sigma-Aldrich Chemical Co., St. Louis, MO), and hydrochloric acid (J.T. Baker, 36%) from Avantor Performance Materials Inc. (Center Valley, PA).
Reagents utilized for the mercury amalgam syntheses [20] of
Results and discussion
In the first step of the NTS method, either butylamine or cyclohexylamine are added in catalytic amounts to facilitate the Knoevenagel reaction process. These amines react nicely with benzaldehye to produce their corresponding imines, which then undergo carbon–carbon bond formation with the enolate of nitroethane. Elimination of the catalytic amines back into the reaction mixture results in nitrostyrene formation. These catalysts are therefore present as impurities in the reductive hydrolysis
Conclusions
The forensic identification and tracking of two new forensic NTS marker compounds 1 and 2 present at low levels in highly refined seized methamphetamine samples was discussed. These compounds were independently identified, synthesized, structurally elucidated, and then used as standards to support forensic analysis. A series of laboratory-generated samples using a variety of nitrostyrene and other related recipe choices were prepared and their profiling results compared well with actual seized
Acknowledgement
The authors are indebted to the DEA Office of Forensic Sciences for supporting this profiling work. -
2024-10-02 at 12:31 AM UTC
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2024-10-02 at 5:47 AM UTC
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2024-10-02 at 6:06 AM UTCHis name is Andrei
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2024-10-02 at 6:40 AM UTC
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2024-10-02 at 6:49 AM UTCHahahhahahahahahhahahahahahahhahahahahahahahahahaaaaaaaaa
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2024-10-08 at 6:56 AM UTC
Originally posted by the man who put it in my hood this is why everyone should learn to make their own organic solar meth from brewing ephedrine and or that one reduction with very easy to stockpile chemicals
Yeah, more people at least. The mandellic acid route is fairly simple but then I started thinking about 4 ethyl phenol from grape juice fermentation. That might end up being a simple route to phenyl acetic acid.
Periodically I smell bandaids for miles... The smell of 4 ethyl phenol possibly. A gang member I know told me they make it in the massive tunnel systems underground. He said in certain areas you can smell it, although he was talking about a different chemical i forget the name of. Also over 500 cave systems here and some unmapped or waiting to be discovered. I figure if theyre using the tunnels they have secret hydraulic doors somewhere.
Caves and tunnels would be legit since nobody pays attention to the homeless that go in and out of them with backpacks full of random stuff.
