Saved in:
Bibliographic Details
Main Authors: Bao, Alicia, He, Jiamian, Hsu, Angel, Manya, Diego, Ji, Zhang
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.00053
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917375797886976
author Bao, Alicia
He, Jiamian
Hsu, Angel
Manya, Diego
Ji
Zhang
author_facet Bao, Alicia
He, Jiamian
Hsu, Angel
Manya, Diego
Ji
Zhang
contents As large language models (LLMs) are increasingly used in domain-specific applications, including climate change and environmental research, understanding their energy footprint has become an important concern. The growing adoption of retrieval-augmented (RAG) systems for climate-domain specific analysis raises a key question: how does the energy consumption of domain-specific RAG workflows compare with that of direct generic LLM usage? Prior research has focused on standalone model calls or coarse token-based estimates, while leaving the energy implications of deployed application workflows insufficiently understood. In this paper, we assess the inference-time energy consumption of two LLM-based climate analysis chatbots (ChatNetZero and ChatNDC) compared to the generic GPT-4o-mini model. We estimate energy use under actual user queries by decomposing each workflow into retrieval, generation, and hallucination-checking components. We also test across different times of day and geographic access locations. Our results show that the energy consumption of domain-specific RAG systems depends strongly on their design. More agentic pipelines substantially increase inference-time energy use, particularly when used for additional accuracy or verification checks, although they may not yield proportional gains in response quality. While more research is needed to further test these initial findings more robustly across models, environments and prompting structures, this study provides a new understanding on how the design of domain-specific LLM products affects both the energy footprint and quality of output.
format Preprint
id arxiv_https___arxiv_org_abs_2604_00053
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The Energy Footprint of LLM-Based Environmental Analysis: LLMs and Domain Products
Bao, Alicia
He, Jiamian
Hsu, Angel
Manya, Diego
Ji
Zhang
Software Engineering
Artificial Intelligence
As large language models (LLMs) are increasingly used in domain-specific applications, including climate change and environmental research, understanding their energy footprint has become an important concern. The growing adoption of retrieval-augmented (RAG) systems for climate-domain specific analysis raises a key question: how does the energy consumption of domain-specific RAG workflows compare with that of direct generic LLM usage? Prior research has focused on standalone model calls or coarse token-based estimates, while leaving the energy implications of deployed application workflows insufficiently understood. In this paper, we assess the inference-time energy consumption of two LLM-based climate analysis chatbots (ChatNetZero and ChatNDC) compared to the generic GPT-4o-mini model. We estimate energy use under actual user queries by decomposing each workflow into retrieval, generation, and hallucination-checking components. We also test across different times of day and geographic access locations. Our results show that the energy consumption of domain-specific RAG systems depends strongly on their design. More agentic pipelines substantially increase inference-time energy use, particularly when used for additional accuracy or verification checks, although they may not yield proportional gains in response quality. While more research is needed to further test these initial findings more robustly across models, environments and prompting structures, this study provides a new understanding on how the design of domain-specific LLM products affects both the energy footprint and quality of output.
title The Energy Footprint of LLM-Based Environmental Analysis: LLMs and Domain Products
topic Software Engineering
Artificial Intelligence
url https://arxiv.org/abs/2604.00053