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spurious scholar

Because if p < 0.05, why not publish?

Step 1: Gather a bunch of data. There are 25,156 variables in my database. The data ranges from the mundane (air pollution in Chicago) to the weird (Hotdogs consumed by Nathan's Hot Dog Eating Competition Champion) to the super-niche (How clickbait-y Numberphile YouTube video titles are, as rated by an AI).
Step 2: Dredge that data to find random correlations between variables. "Dredging data" means taking one variable and correlating it against every other variable just to see what sticks. It's a dangerous way to go about analysis, because any sufficiently large dataset will yield strong correlations completely at random.

Fun fact: the chart used on the wikipedia page to demonstrate data dredging is also from me. I've been being naughty with data since 2014.

Step 3: Calculate the correlation coefficient, confidence interval, and p-value to see if the connection is statistically significant. "Statistically significant" is a misleading term. It sounds like it means "statistically significant" because, you know, those are the same two words. Unfortunately statistical significance is a technical term that means mumble mumble at least as extreme mumble mumble null hypothesis mumble mumble probability mumble mumble p-values.

You know what? Forget the technical definition. "Statistically significant" just means "someone did some fancy math."

I really did the fancy math below and you can check it by clicking on the "view detailed data" link under each paper. And these really do qualify as "statistically significant" in the technical sense. It's just that "statistically significant" does not mean the results are "significant."

Step 4: If it is, have a large language model draft a research paper.
Step 5: Remind everyone that these papers are AI-generated and are not real. Seriously, just pick one and read the lit review section. The silliness of the papers is an artifact of me (1) having fun and (2) acknowledging that realistic-looking AI-generated noise is a real concern for academic research (peer reviews in particular).

The papers could sound more realistic than they do, but I intentionally prompted the model to write papers that look real but sound silly.

Also: every page says "This paper is AI-generated" at the bottom and the first letters of the names of the authors always spell out C-H-A-T-G-P-T.

Step 6: ...publish:

Wacky West Virginia Votes and Bosnian Electricity: A Bizarre Back-and-Forth
Journal of Quirky Regional Politics
r=0.969 · 95% conf. int. [0.831,0.994] · r2=0.938 · p < 0.01
Generated Jan 2024 · View data details

From GMO to GOP: Unraveling the Cotton-nection Between Genetically Modified Cotton and Republican Votes in Louisiana
Journal of Agro-Political Dynamics
r=0.997 · 95% conf. int. [0.971,1.000] · r2=0.994 · p < 0.01
Generated Jan 2024 · View data details

Looking Beyond the Stars: The Neptune of Republican Votes in Washington, D.C.
Journal of Political Astrology
r=0.936 · 95% conf. int. [0.783,0.982] · r2=0.876 · p < 0.01
Generated Jan 2024 · View data details

Blue Wave and Black Gold: Investigating the Surprising Link Between Democratic Votes in New Jersey and Petroleum Consumption in Brunei
The Journal of Eclectic Social Science Research
r=0.965 · 95% conf. int. [0.865,0.991] · r2=0.930 · p < 0.01
Generated Jan 2024 · View data details

The Thaddeus Effect: A Statistical Analysis of the Correlation between Name Popularity and Libertarian Presidential Votes in Maine
The Journal of Quirky Sociological Analyses
r=0.940 · 95% conf. int. [0.734,0.988] · r2=0.884 · p < 0.01
Generated Jan 2024 · View data details

LIBERTARIAN SENATE VOTES AND WORLD SERIES RUNS: A CORRELATION THAT PUNS ABOVE THE REST?
The Journal of Satirical Scientific Studies
r=0.914 · 95% conf. int. [0.588,0.985] · r2=0.835 · p < 0.01
Generated Jan 2024 · View data details

Unearthly Connections: An Extraterrestrial Approach to Analyzing Votes for the Republican Presidential Candidate in Oregon
The Cosmic Observer: Journal of Interstellar Politics and Societal Analysis
r=0.855 · 95% conf. int. [0.552,0.959] · r2=0.731 · p < 0.01
Generated Jan 2024 · View data details

Brake-ing the Mold: The Libertarian Candidate's Influence on Parking Brake Recalls in California
The Journal of Political Automotive Engineering
r=0.867 · 95% conf. int. [0.524,0.968] · r2=0.752 · p < 0.01
Generated Jan 2024 · View data details

The Feathered Ballot: Correlating Republican Votes in Ohio with Avian Rainy Day Curiosity
Journal of Avian Political Behavior
r=0.906 · 95% conf. int. [0.357,0.990] · r2=0.821 · p < 0.05
Generated Jan 2024 · View data details

Votes and Voyeurs: The Distracted Boyfriend Meme and Republican Senators in Minnesota
The International Journal of Memetics and Political Behavior
r=0.950 · 95% conf. int. [0.607,0.995] · r2=0.903 · p < 0.01
Generated Jan 2024 · View data details

The Big and the Cheesy: A Gouda Look at American Cheese Consumption and Votes for the Republican Presidential Candidate in Pennsylvania
Journal of Dairy Politics
r=0.949 · 95% conf. int. [0.735,0.991] · r2=0.900 · p < 0.01
Generated Jan 2024 · View data details

The Ohio Show: Democrat Votes and Insurance Underwriters' Bloat
The Journal of Political Circus Studies
r=-0.982 · 95% conf. int. [-0.998,-0.838] · r2=0.964 · p < 0.01
Generated Jan 2024 · View data details

Goal of the GOP: Exploring the Correlation Between Republican Votes in New Hampshire and Frank Lampard's Premier League Goal Tally
The Journal of Political Sports Science
r=0.994 · 95% conf. int. [0.945,0.999] · r2=0.988 · p < 0.01
Generated Jan 2024 · View data details

Up in Smoke: An Analysis of the Relationship Between Tobacco Spending and Democratic Votes in Minnesota
The Journal of Whimsical Political Science
r=0.957 · 95% conf. int. [0.775,0.992] · r2=0.916 · p < 0.01
Generated Jan 2024 · View data details

Goal-tally Politics: A Correlational Analysis of Votes for the Republican Presidential Candidate in Wyoming and Frank Lampard's Premier League Performance
The Journal of Sports and Political Science
r=0.996 · 95% conf. int. [0.963,1.000] · r2=0.992 · p < 0.01
Generated Jan 2024 · View data details

Burning Down the House: Correlating Votes for the Republican Presidential Candidate in Hawaii with Kerosene Consumption in Ecuador
The International Journal of Political Pyrotechnics
r=0.906 · 95% conf. int. [0.555,0.983] · r2=0.820 · p < 0.01
Generated Jan 2024 · View data details

Making Sausage and Winning Hearts: A Correlational Study of Republican Votes in Virginia and Nathan's Hot Dog Eating Competition Champions' Consumption
The Journal of Gastronomic Politics
r=0.929 · 95% conf. int. [0.744,0.982] · r2=0.863 · p < 0.01
Generated Jan 2024 · View data details

3 Strikes and You're Utah: The Mega Influence of Mega Millions on Republican Votes for Senators in the Beehive State
The Journal of Political Polling and Punditry
r=0.962 · 95% conf. int. [0.687,0.996] · r2=0.926 · p < 0.01
Generated Jan 2024 · View data details

Librarianomics: The Dewey Decimal of Political Influence - A Study of the Relationship between Associates Degrees in Library Science and Democrat Votes for Senators in Iowa
The Journal of Political Bibliometrics
r=0.998 · 95% conf. int. [-1.000,1.000] · r2=0.996 · p < 0.05
Generated Jan 2024 · View data details

Kodi's Libertarian Leverage: Longitudinal Links between New Hampshire Nom de Plume Popularity and Political Preferences
The Journal of Quirky Quantitative Research
r=0.803 · 95% conf. int. [0.391,0.947] · r2=0.644 · p < 0.01
Generated Jan 2024 · View data details

Harry Potter and Iowa Republican Voter Plotter: A Correlational Analysis
The International Journal of Wizarding Psychology
r=0.819 · 95% conf. int. [0.021,0.979] · r2=0.670 · p < 0.05
Generated Jan 2024 · View data details

Calling Senators and Sprinting to Votes: A Correlative Examination of Republican Voting Patterns in Louisiana and Sprint Customer Satisfaction
The Journal of Political Velocity and Consumer Sentiment
r=0.919 · 95% conf. int. [0.423,0.991] · r2=0.845 · p < 0.01
Generated Jan 2024 · View data details

A Tale of Red States and Marketing Fates: How Republican Votes Relate to the Number of Idaho Marketing Mates
The Journal of Political Psychology and Regional Marketing
r=0.970 · 95% conf. int. [0.747,0.997] · r2=0.942 · p < 0.01
Generated Jan 2024 · View data details

Libertarian Votica: A Correlative Study of the Danica Effect on Senatorial Elections in Connecticut
The Journal of Political Quirkiness
r=0.931 · 95% conf. int. [0.728,0.984] · r2=0.867 · p < 0.01
Generated Jan 2024 · View data details

Emani-tion and Political Affiliation: A Correlation Study of Emani's Popularity and Democrat Votes
The Journal of Humor and Political Science
r=0.959 · 95% conf. int. [0.785,0.993] · r2=0.920 · p < 0.01
Generated Jan 2024 · View data details


Currently viewing 25 of 4,731 spurious research papers

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Why this works

  1. Data dredging: I have 25,156 variables in my database. I compare all these variables against each other to find ones that randomly match up. That's 632,824,336 correlation calculations! This is called “data dredging.” Fun fact: the chart used on the wikipedia page to demonstrate data dredging is also from me. I've been being naughty with data since 2014.
    Instead of starting with a hypothesis and testing it, I isntead tossed a bunch of data in a blender to see what correlations would shake out. It’s a dangerous way to go about analysis, because any sufficiently large dataset will yield strong correlations completely at random.
  2. Lack of causal connection: There is probably no direct connection between these variables, despite what the AI says above. Because these pages are automatically generated, it's possible that the two variables you are viewing are in fact causually related. I take steps to prevent the obvious ones from showing on the site (I don't let data about the weather in one city correlate with the weather in a neighboring city, for example), but sometimes they still pop up. If they are related, cool! You found a loophole.
    This is exacerbated by the fact that I used "Years" as the base variable. Lots of things happen in a year that are not related to each other! Most studies would use something like "one person" in stead of "one year" to be the "thing" studied.
  3. Observations not independent: For many variables, sequential years are not independent of each other. You will often see trend-lines form. If a population of people is continuously doing something every day, there is no reason to think they would suddenly change how they are doing that thing on January 1. A naive p-value calculation does not take this into account. You will calculate a lower chance of "randomly" achieving the result than represents reality.

    To be more specific: p-value tests are probability values, where you are calculating the probability of achieving a result at least as extreme as you found completely by chance. When calculating a p-value, you need to assert how many "degrees of freedom" your variable has. I count each year (minus one) as a "degree of freedom," but this is misleading for continuous variables.

    This kind of thing can creep up on you pretty easily when using p-values, which is why it's best to take it as "one of many" inputs that help you assess the results of your analysis.
  4. Outliers: Some datasets here have outliers which drag up the correlation. In concept, "outlier" just means "way different than the rest of your dataset." When calculating a correlation like this, they are particularly impactful because a single outlier can substantially increase your correlation.

    Because this page is automatically generated, I don't know whether any of the charts displayed on it have outliers. I'm just a footnote. ¯\_(ツ)_/¯
    I intentionally mishandeled outliers, which makes the correlation look extra strong.



Spurious Scholar was launched January 27, 2024. If you have feedback on it, I'd love to hear from you! Shoot me a note: feedback@tylervigen.com.


Project by Tyler Vigen
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